Rasp Tool

ABSTRACT

A rasp tool for preparing an implantation site includes a first arm, a second arm, a first wing, and a second wing. The first arm and the second arm are pivotally connected to one another. The first wing extends from a distal end of the first arm and includes a sharp tip positioned at a distal end of the first wing and configured to ease insertion into the implantation site, and a cutout defined along a first side of the first wing. The second wing extends from a distal end of the second arm. The first wing and the second wing are configured to move between a closed position and an open position by pivoting the first arm and the second arm, and the second wing is received at least partially within the cutout when the first wing and the second wing are in the closed position.

CROSS-REFERENCE TO RELATED APPLICATIONS

This application is a division of U.S. application Ser. No. 14/713,006, filed May 15, 2015, which is a continuation of PCT Application No. PCT/US2013/070590 filed Nov. 18, 2013 which claims priority to U.S. Provisional Application No. 61/727,411 filed Nov. 16, 2012, the entire contents of which are hereby incorporated by reference.

FIELD OF THE INVENTION

The invention relates generally to devices for use during spinal surgery, and methods pertaining thereto, and more particularly to devices and methods for providing spacing between adjacent spinous processes.

BACKGROUND OF THE INVENTION

Spinal discs and/or other vertebral changes can cause spinal disease that often leads to patient discomfort or even paralysis. For example, intervertebral spinal discs, which lie between adjacent vertebrae, can break down or degenerate, resulting in disc fluid loss and consequently resulting in a loss of disc flexibility. In addition, discs can become thinner, allowing the vertebrae to move closer together, may tear or crack in the outer layer and/or the annulus of the disc, and/or bulge outwardly. Facet joint degeneration may also lead to spinal disease. Physical trauma (e.g., accidents, injuries, strains, etc.) may cause spinal column changes, and spinal stenosis can cause the spinal canal to narrow due to excessive bone growth and/or thickening of tissue. In all of these conditions, the spinal canal through which the spinal cord and the spinal nerve roots pass may become narrowed, creating pressure on nerve tissue. Such pressure can cause pain, numbness, weakness, or even paralysis in various parts of the body.

Some methods for treating spinal diseases, such as those described above, limit the movement of adjacent vertebrae relative to one another to limit the additional pressure on the local nerve tissue by maintaining a minimum disc space and/or space surrounding the adjacent vertebrae. Various methods have been performed to maintain this minimum space, including disc implants and spinal fusions. One method includes implanting a spacer between two adjacent posteriorly extending spinous processes, which in effect maintains a maximum space between the corresponding vertebrae. Some existing spacer implant devices are implanted by affixing the device to adjacent spinous processes. Existing spacer implants, however, do not provide complete access to insert bone growth promoting substances into the spacer after implant. In addition, existing spacer implants do not provide structural integrity between two adjacently implanted spacers. Moreover, the procedures required to implant existing spacer implant devices are overly complicated, requiring the use of multiple tools to position, tighten, and secure the implants to the spinous processes.

Therefore, there remains a need for improved interspinous process spacer implants.

SUMMARY OF THE INVENTION

Various embodiments described herein provide devices and associated methods for treating spinal disease. According to one embodiment, an interspinous process spacing device is provided. The device includes a first attachment side and a second attachment side, whereby each attachment side includes one or more slots formed in the outer surface and oriented proximate one end for receiving fasteners extending inwardly from a second interspinous process spacing device. The device further includes a spacer tray positioned between the first attachment side and the second attachment side, the spacer tray extending in a substantially perpendicular orientation from the first attachment side and slideably insertable through a tray slot formed in the second attachment side, wherein the spacer tray is adapted to retain adjacent spinous processes in a spaced apart orientation. The device further includes securing means for securing the second attachment side relative to the first attachment side, wherein, upon securing the second attachment side relative to the first attachment side by the securing means, the interspinous process spacing device is engaged with the adjacent spinous processes.

According to one embodiment, an interspinous process spacing device is provided with a first attachment side and a second attachment side, whereby each attachment side includes one or more slots formed in the outer surface and oriented proximate one end for receiving fasteners extending inwardly from a second interspinous process spacing device. In one embodiment, the slots are elongated to receive a fastener from a second interspinous process spacing device along a range of distances therein. In one embodiment, the slots may be narrowed by a clamping mechanism and thereby tightened to secure a fastener received therein.

According to one embodiment, an interspinous process spacing device is provided with a first attachment side and a second attachment side, whereby each attachment side includes one or more fasteners extending inwardly from each of the first attachment side and second attachment side. In one embodiment, the fasteners are each adjustably carried within an elongated fastener frame to engage a slot in another interspinous process spacing device along a range of distances therefrom. In one embodiment, the fasteners may be secured at a selected position within the fastener frame and thereby at a set distance away from an adjacent interspinous process spacing device.

In one aspect, the spacer tray comprises an arcuate cross-sectional shape and is substantially open and accessible from the posterior direction. The spacer tray is adapted to retain bone growth promoting substance and to maximize the open space above the spacer tray and between the spinous processes, wherein the bone growth promoting substance is packable after engaging the first attachment side and the second attachment side to adjacent spinous processes. In another embodiment, the spacer tray comprises two separate members forming a space therebetween.

According to one aspect, the securing means can include at least one of: (a) at least one worm drive assembly; (b) at least one rack and pinion assembly; (c) at least one screw extending between and operably connecting the first attachment side and the second attachment side; (d) a geared rack and ratchet assembly; or (e) at least one set screw assembly.

In one aspect, there are at least two spaced apart securing mechanisms extending between and operably connecting the first attachment side and the second attachment side, wherein each of the at least two spaced apart securing mechanisms can be independently and incrementally actuated causing each end of the attachment sides to engage the respective spinous process independently.

According to one aspect, the interspinous process spacing device is a first interspinous process spacing device, and a second interspinous process spacing device is included. The second interspinous process spacing device includes a first bent attachment side and a second bent attachment side, wherein each bent attachment side comprises a substantially flat end and an offset end adapted to overlap an adjacent portion of the respective attachment sides of the first interspinous process spacing device.

According to one aspect including a second interspinous process spacing device, each of the first attachment side and the second attachment side of the second interspinous process spacing device has one or more integration means for integrating and attaching the offset end of the second interspinous process spacing device with a portion of the respective attachment side of the first interspinous process spacing device.

According to various aspects, the first interspinous process spacing device may be implantable inferior or superior to the second interspinous process spacing device.

In a different embodiment, an interspinous process spacing system is provided. The interspinous process spacing system includes a first interspinous process spacing device and a second interspinous process spacing device. The interspinous process spacing device comprises two substantially flat attachment sides and a first spacer tray positioned therebetween, wherein one of the two substantially flat attachment sides is slideably positionable over the spacer tray. The second interspinous process spacing device comprises two bent attachment sides and a second spacer tray positioned therebetween, wherein each of the bent attachment sides comprises a substantially flat end and an offset end. After implantation of the first interspinous process spacing device on a first and a second adjacent spinous process, the offset ends of the two bent attachment sides of the second interspinous process spacing device at least partially overlap respective adjacent ends of the substantially flat attachment sides of the first interspinous process spacing device when implanting the second interspinous process spacing device on the second and a third spinous process adjacent to the second spinous process.

According to yet another embodiment, an interspinous process spacing device kit is provided. The interspinous process spacing device kit may include: a first interspinous process spacing device comprising a first attachment side and a second attachment side, the first and the second attachment sides of the first interspinous process spacing device having a substantially flat configuration; at least one additional interspinous process spacing device comprising a first attachment side and a second attachment side, the first and the second attachment sides of the at least one additional interspinous process spacing device having a bent configuration adapted to overlap a portion of a respective attachment side of the first interspinous process spacing device; and at least one insertion instrument adapted for retaining at least one of the first interspinous processing spacing devices or the at least one additional interspinous process spacing device and implanting the same.

The kit may include a first insertion instrument and a second insertion instrument, wherein the first insertion instrument is adapted for implanting at least one of the first interspinous process spacing devices or at least one additional interspinous process spacing device in a first orientation, and the second insertion instrument is adapted for implanting at least one of the first interspinous processing spacing devices or the at least one additional interspinous process spacing device in a second orientation. Each insertion instrument may include a first arm and a second arm, wherein the second arm is removably and pivotally attachable to the first arm.

According to one embodiment, an interspinous process spacing device is provided. The device includes a first attachment side and a second attachment side, whereby each attachment side includes one or more slots formed in the outer surface and oriented proximate one end for receiving fasteners extending inwardly from a second interspinous process spacing device. The device further includes a spacer tray positioned between the first attachment side and the second attachment side, the spacer tray extending in a substantially perpendicular orientation from the first attachment side and slideably insertable through a tray slot formed in the second attachment side, wherein the spacer tray includes a trough formed in a top surface of the spacer tray, and wherein the spacer tray is adapted to retain adjacent spinous processes in a spaced apart orientation. The device further includes securing means configured to engage the trough of the spacer tray to secure the second attachment side relative to the first attachment side, wherein, upon securing the second attachment side relative to the first attachment side by the securing means, the interspinous process spacing device is engaged with the adjacent spinous processes.

According to another embodiment, an interspinous process spacing device is provided. The device includes a first attachment side, a second attachment side, a spacer tray, and a securing means. The spacer tray extends from the first attachment side and is slideably insertable through a spacer tray slot formed in the second attachment side. The spacer tray is adapted to be positioned between a spinous process of a first vertebra and a spinous process of an adjacent second vertebra, and the spacer tray includes a trough formed in a top surface of the spacer tray. The securing means is configured to engage the trough of the spacer tray to secure the second attachment side relative to the first attachment side.

According to yet another embodiment, an interspinous process spacing device is provided. The device includes a first attachment side, a second attachment side, and a spacer tray. The spacer tray extends from the first attachment side and is slideably insertable through a spacer tray slot formed in the second attachment side. The spacer tray is adapted to be positioned between a spinous process of a first vertebra and a spinous process of an adjacent second vertebra. The first attachment side and the second attachment side each comprise a central portion, a first wing portion, and a second wing portion, wherein inner surfaces of the first wing portion and the second wing portion are angled relative to an inner surface of the central portion.

According to another embodiment, a rasp tool for preparing an implantation site for an interspinous process spacing device between a first spinous process and an adjacent second spinous processes is provided. The rasp tool includes a first arm having a proximal end and a distal end, and a second arm having a proximal end and a distal end, wherein the first arm and the second arm are pivotally connected to one another. The rasp tool also includes a first measurement wing extending from the distal end of the first arm, and a second measurement wing extending from the distal end of the second arm. The first measurement wing includes a sharp tip configured to ease insertion between the first spinous process and the second spinous process. The first measurement wing and the second measurement wing are configured to move between a closed position and an open position by pivoting the first arm and the second arm.

According to yet another embodiment, a method for implanting an interspinous process spacing device is provided.

According to yet another embodiment, a method for treating a spinal disorder including implanting one or more interspinous process spacing devices is provided.

According to yet another embodiment, a method for manufacturing an interspinous process spacing device is provided.

BRIEF DESCRIPTION OF THE DRAWINGS

The objects and advantages of the present invention will be better understood and more readily apparent when considered in conjunction with the following detailed description and accompanying drawings which illustrate, by way of example, embodiments of interspinous process spacing devices, and in which:

FIG. 1 is a profile view of three interspinous process spacing devices, according to an example embodiment.

FIG. 2A is an isometric view of a second attachment side of an interspinous process spacing device, according to an example base plate embodiment. FIG. 2B is a top view of a second attachment side of an interspinous process spacing device, according to an example embodiment. FIG. 2C is a back view of a second attachment side of an interspinous process spacing device, according to an example embodiment. FIG. 2D is a side view of a second attachment side of an interspinous process spacing device, according to an example embodiment. FIG. 2E is a top view a first attachment side of an interspinous process spacing device, according to an example embodiment. FIG. 2F is an isometric view of a first attachment side of an interspinous process spacing device, according to an example embodiment. FIG. 2G is a side view of a first attachment side of an interspinous process spacing device, according to an example embodiment. FIG. 2H is a back view of a first attachment side of an interspinous process spacing device, according to an example embodiment.

FIG. 3A is an isometric view of a second attachment side of an interspinous process spacing device, according to an example linker plate embodiment. FIG. 3B is a top view of a second attachment side of an interspinous process spacing device, according to an example embodiment. FIG. 3C is a back view of a second attachment side of an interspinous process spacing device, according to an example embodiment. FIG. 3D is a side view of a second attachment side of an interspinous process spacing device, according to an example embodiment. FIG. 3E is a top view a first attachment side of an interspinous process spacing device, according to an example embodiment. FIG. 3F is an isometric view of a first attachment side of an interspinous process spacing device, according to an example embodiment. FIG. 3G is a side view of a first attachment side of an interspinous process spacing device, according to an example embodiment. FIG. 3H is a back view of a first attachment side of an interspinous process spacing device, according to an example embodiment.

FIGS. 4A-4E are views of securing means integrated with interspinous process spacing devices, according to example base plate and overlapping link plate embodiments. FIG. 4A is a top view of two interlinked interspinous process spacing devices. FIG. 4B is a top view of one secured interspinous process spacing base device and one unsecured interspinous process spacing link device. FIG. 4C is an isometeric view of one secured interspinous process spacing base device and one unsecured interspinous process spacing link device. FIG. 4D is a back (outside) view of a first attachment side of an interspinous process spacing device having a base plate fastened to a link plate device. FIG. 4E is a back view of a second attachment side of an interspinous process spacing device having a base plate fastened to a link plate device.

FIG. 5A is a back view of a first attachment side of an interspinous process spacing device having a base plate fastened to a link plate device showing maximum rotational range when connected to a first aperture, according to an example embodiment. FIG. 5B is a back view of a first attachment side of an interspinous process spacing device having a base plate fastened to a link plate device showing maximum rotational range when connected to a second aperture, according to an example embodiment. FIG. 5C is a back view of a first attachment side of an interspinous process spacing device having a base plate with multiple overlapping apertures in an inch-worm formation, for receiving a fastener of another link plate device, according to an example embodiment.

FIG. 6A is an isometric view of a set of a base plate interspinous process spacing devices having a gradient of spacer tray widths, according to an example embodiment. FIG. 6B is an isometric view of a set of link plate interspinous process spacing devices having a gradient of spacer tray widths, according to an example embodiment.

FIG. 7A is a side view of a L5-S1 sacrum interspinous process spacing base device, according to an example embodiment. FIG. 7B is an isometric view of a L5-S1 sacrum interspinous process spacing base device, according to an example embodiment. FIG. 7C is an isometric view of a first attachment side of an L5-S1 sacrum interspinous process spacing base device, according to an example embodiment. FIG. 7D is an isometric view of an alternative L5-S1 sacrum interspinous process spacing link device, according to an example embodiment. FIG. 7E is an isometric view of a second attachment side of a L5-S1 sacrum interspinous process spacing link device, according to an example embodiment.

FIG. 8A is an isometric view of an interspinous process spacing device, according to an example embodiment. FIG. 8B is an exploded isometric view of an interspinous process spacing device, according to an example embodiment. FIG. 8C is an exploded isometric view of an interspinous process spacing device, according to an example embodiment. FIG. 8D is a side view of an interspinous process spacing device, according to an example embodiment.

FIG. 9A is an isometric view of a first attachment side of an interspinous process spacing device link plate with an alternative spacer tray, according to an example embodiment. FIG. 9B is an exploded isometric view of a first attachment side of an interspinous process spacing device link plate with an alternative spacer tray, according to an example embodiment. FIG. 9C is an exploded isometric view of a first attachment side of an interspinous process spacing device link plate with an alternative spacer tray, according to an example embodiment. FIG. 9D is an isometric view of a first attachment side of an interspinous process spacing device link plate with an alternative spacer tray, according to an example embodiment.

FIG. 10 is an isometric view of an alternative interspinous process spacing device, according to an example embodiment.

FIG. 11A is an isometric view of an alternative interspinous process spacing device, according to an example embodiment. FIG. 11B is an isometric view of the first attachment side of the alternative interspinous process spacing device integrating an alternative worm-gear advancement mechanism for the first and second attachment sides, according to an example embodiment. FIG. 11C is an isometric view of the alternative interspinous process spacing device, according to an example embodiment. FIG. 11D is an isometric view of the alternative interspinous process spacing device implanted onto a spine, according to an example embodiment.

FIG. 12A is an isometric outside view of the first attachment side of the alternative interspinous process spacing device, according to an example embodiment. FIG. 12B is an isometric inside view of the first attachment side of the alternative interspinous process spacing device, according to an example embodiment. FIG. 12C is an isometric view of a floating receiving member of the alternative interspinous process spacing device, according to an example embodiment. FIG. 12D is an isometric view of a floating receiving member of the alternative interspinous process spacing device, according to an example embodiment. FIG. 12E is an isometric view of a floating receiving member of the alternative interspinous process spacing device, according to an example embodiment. FIG. 12F is a side view of a floating receiving member of the alternative interspinous process spacing device, according to an example embodiment. FIG. 12G is an isometric view of the interface of a floating receiving member integrating with the first attachment side of the alternative interspinous process spacing device, according to an example embodiment. FIG. 12H is an inner isometric view of the interface of a floating receiving member integrating with the first attachment side of the alternative interspinous process spacing device, according to an example embodiment. FIG. 12I is an outside rear view of the interface of a floating receiving member integrating with the first attachment side of the alternative interspinous process spacing device, according to an example embodiment. FIG. 12J is an isometric view of an alternative interspinous process spacing device, according to an example embodiment. FIG. 12K is an isometric view of an alternative interspinous process spacing device integrating an alternative advancement mechanism for the first and second attachment sides, according to an example embodiment. FIG. 12L is an isometric view of an alternative interspinous process spacing device integrating an alternative advancement mechanism for the first and second attachment sides, according to an example embodiment.

FIG. 13A is an isometric view of a top down or universal surgical instrument for implanting and compressing/advancing two attachment sides of an interspinous process spacing device, according to an example embodiment. FIG. 13B is a side view of a universal surgical instrument for implanting and compressing/advancing two attachment sides of an interspinous process spacing device, according to an example embodiment. FIG. 13C is a side view of a universal surgical instrument for implanting and compressing/advancing two attachment sides of an interspinous process spacing device, according to an example embodiment. FIG. 13D is a detailed side view of a universal surgical instrument for implanting and compressing/advancing two attachment sides of an interspinous process spacing device, according to an example embodiment.

FIG. 14A is a side view of a first arm of a top down or universal surgical instrument for implanting and compressing/advancing two attachment sides of an interspinous process spacing device, according to an example embodiment. FIG. 14B is an alternative side view of a first arm of the example embodiment. FIG. 14C is an alternative side view of a first arm of the example embodiment. FIG. 14D is a side view of a second arm of the example embodiment. FIG. 14E is an alternative side view of a second arm of the example embodiment. FIG. 14F is an alternative side view of a second arm of the example embodiment.

FIG. 15A is a side view of a separate first and second arm of a top down or universal surgical instrument for implanting and compressing/advancing two attachment sides of an interspinous process spacing device, according to an example embodiment. FIG. 15B is a side view of a further advanced (almost engaged) first and second arm of a top down surgical instrument for implanting and compressing/advancing two attachment sides of an interspinous process spacing device, according to an example embodiment.

FIG. 16A is a side view of a top down or universal surgical instrument for implanting and compressing/advancing two attachment sides of an interspinous process spacing device showing an unengaged mechanical actuation means, according to an example embodiment. FIG. 16B is a side view of a top down surgical instrument for implanting and compressing/advancing two attachment sides of an interspinous process spacing device showing an engaged mechanical actuation means, according to an example embodiment. FIG. 16C is an isometeric view of a top down surgical instrument for implanting and compressing/advancing two attachment sides of an interspinous process spacing device showing the mechanical actuation means, according to an example embodiment.

FIG. 17A is a side view of a second inserter arm of a surgical instrument for implanting an interspinous process spacing device, according to an example embodiment. FIG. 17B is an alternative side view of the second inserter arm of the example embodiment. FIG. 17C is an alternative side view of the second inserter arm of the example embodiment. FIG. 17D is a side view of the first arm of the example embodiment. FIG. 17E is an alternative side view of a first arm of the example embodiment. FIG. 17F is an alternative side view of a first arm of the example embodiment.

FIG. 18A is an isometric view of a first and second inserter arm of a surgical instrument for implanting an interspinous process spacing device, according to an example embodiment. FIG. 18B is a view of the retained first and second inserter arms of the example embodiment. FIG. 18C is a side view of the retained first and second inserter arms of the example embodiment.

FIG. 19A is an isometric view of a compressor tool positioning first and second inserter arms of a surgical instrument for implanting an interspinous process spacing device, according to an example embodiment. FIG. 19B is an isometric view of a compressor tool positioning first and second inserter arms of a surgical instrument for implanting an interspinous process spacing device, according to an example embodiment.

FIG. 20A is a side view of a compressor tool for implanting an interspinous process spacing device, according to an example embodiment. FIG. 20B is an isometric view of a compressor tool for implanting an interspinous process spacing device, according to an example embodiment. FIG. 20C is an alternative side view of a compressor tool for implanting an interspinous process spacing device, according to an example embodiment.

FIG. 21A is a side view of an interspinous process space measurement instrument, according to an example embodiment. FIG. 21B is an isometric view of an interspinous process space measurement instrument, according to an example embodiment. FIG. 21C is an isometric view of an interspinous process space measurement instrument, according to an example embodiment. FIG. 21D is a top view of an interspinous process space measurement instrument, according to an example embodiment.

FIG. 22A is a side view of an embodiment of a link wing with an extension fastener adjustably slideable within a fastener frame, according to an example embodiment. FIG. 22B is a side view of a base wing with a single hole, according to an example embodiment.

FIG. 23A is a side view of an alternative link wing with an elongated slot to receive a fastener, according to an example embodiment. FIG. 23B is a side view of an alternative base wing with two elongated slots, according to an example embodiment.

FIG. 24A is an exploded side view of a first and second inserter arm of a surgical instrument for implanting an interspinous process spacing device, according to an example embodiment. FIG. 24B is a close-up view of the pivoting member of the second inserter arm of the example embodiment. FIG. 24C is a close-up view of the pivot channel of the first inserter arms of the example embodiment.

FIG. 25A is an isometric back view of a rasping tool for implanting an interspinous process spacing device, according to an example embodiment. FIG. 25B is an isometric front view of a rasping tool for implanting an interspinous process spacing device, according to an example embodiment. FIG. 25C is a side view of a rasping tool for implanting an interspinous process spacing device, according to an example embodiment.

FIG. 26A is an isometric view of a first attachment side of an interspinous process spacing device, according to an example base plate embodiment. FIG. 26B is a top view of a first attachment side of an interspinous process spacing device, according to an example embodiment. FIG. 26C is a front view of a first attachment side of an interspinous process spacing device, according to an example embodiment. FIG. 26D is a back view of a first attachment side of an interspinous process spacing device, according to an example embodiment. FIG. 26E is a side view of a first attachment side of an interspinous process spacing device, according to an example embodiment. FIG. 26F is a section view of a first attachment side of an interspinous process spacing device, according to an example embodiment. FIG. 26G is a detailed section view of a first attachment side of an interspinous process spacing device, according to an example embodiment. FIG. 26H is a section view of a first attachment side of an interspinous process spacing device, according to an example embodiment.

FIG. 27A is an isometric view of a first attachment side of an interspinous process spacing device, according to an example base plate embodiment. FIG. 27B is a side view of a first attachment side of an interspinous process spacing device, according to an example embodiment.

FIG. 28A is an isometric view of a first attachment side and a second attachment side of an interspinous process spacing device, according to an example embodiment, shown in a spaced apart state. FIG. 28B is an isometric view of a first attachment side and a second attachment side of an interspinous process spacing device, according to an example embodiment, shown in a spaced apart state. FIG. 28C is an bottom view of a first attachment side and a second attachment side of an interspinous process spacing device, according to an example embodiment, shown in a spaced apart state. FIG. 28D is a front view of a first attachment side and a second attachment side of an interspinous process spacing device, according to an example embodiment, shown in a spaced apart state. FIG. 28E is a side view of a first attachment side and a second attachment side of an interspinous process spacing device, according to an example embodiment, shown in an attached state. FIG. 28F is a top view of a first attachment side and a second attachment side of an interspinous process spacing device, according to an example embodiment, shown in an attached state.

FIG. 29A is an isometric view of a first attachment side and a second attachment side of an interspinous process spacing device, according to an example embodiment, shown in an attached state. FIG. 29B is an isometric view of a first attachment side and a second attachment side of an interspinous process spacing device, according to an example embodiment, showing rotation of angled wings. FIG. 29C is an isometric view of a first attachment side and a second attachment side of an interspinous process spacing device, according to an example embodiment, showing rotation of angled wings.

FIG. 30A is a front view of a second attachment side of a first interspinous process spacing device and a second attachment side of a second interspinous process spacing device, according to an example embodiment, shown in an attached state. FIG. 30B is a front view of a second attachment side of a first interspinous process spacing device and a second attachment side of a second interspinous process spacing device, according to an example embodiment, shown in an attached state. FIG. 30C is a front view of a second attachment side of a first interspinous process spacing device and a second attachment side of a second interspinous process spacing device, according to an example embodiment, showing rotation of the second attachment side of the first interspinous process spacing device.

FIG. 31A is an isometric view of a rasp tool, according to an example embodiment, showing first and second interspinous process spacing device measurement wings in a closed state. FIG. 31B is an exploded isometric view of a rasp tool, according to an example embodiment. FIG. 31C is a detailed isometric view of a rasp tool, according to an example embodiment, showing first and second interspinous process spacing device measurement wings in a closed state. FIG. 31D is a detailed isometric view of a rasp tool, according to an example embodiment, showing first and second interspinous process spacing device measurement wings in a closed state. FIG. 31E is a detailed isometric view of a rasp tool, according to an example embodiment, showing first and second interspinous process spacing device measurement wings in an open state.

FIG. 32A is an isometric view of a first attachment side of an interspinous process spacing device, according to an example base plate embodiment. FIG. 32B is a top view of a first attachment side of an interspinous process spacing device, according to an example embodiment. FIG. 32C is a front view of a first attachment side of an interspinous process spacing device, according to an example embodiment. FIG. 32D is a side view of a first attachment side of an interspinous process spacing device, according to an example embodiment. FIG. 32E is a section view of a first attachment side of an interspinous process spacing device, according to an example embodiment.

FIG. 33A is an isometric view of a first attachment side of an interspinous process spacing device, according to an example base plate embodiment. FIG. 33B is a top view of a first attachment side of an interspinous process spacing device, according to an example embodiment. FIG. 33C is a front view of a first attachment side of an interspinous process spacing device, according to an example embodiment. FIG. 33D is a side view of a first attachment side of an interspinous process spacing device, according to an example embodiment.

FIG. 33E is a section view of a first attachment side of an interspinous process spacing device, according to an example embodiment.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

As required, detailed embodiments of the invention are disclosed herein. However, it is to be understood that the disclosed embodiments are merely exemplary of the invention, which may be embodied in various forms. Therefore, specific structural and functional details disclosed herein are not to be interpreted as limiting, but merely as a basis for the claims and as a representative basis for teaching one skilled in the art to variously employ the invention in virtually any appropriately detailed structure.

Embodiments of the invention provide interspinous process spacing devices and methods for their use and manufacture. As described above, an interspinous process spacing device provides a spacer inserted between posteriorly extending spinous processes of adjacent vertebrae to maintain minimum spacing between the spinous processes. Accordingly, a single interspinous process spacing device is designed to limit movement of only two adjacent vertebrae. According to certain embodiments described herein, an interspinous process spacing system is provided with at least two individual interspinous process spacing devices implantable in an integrated, overlapping configuration. This integrated and overlapping configuration improves the stability of the adjacent vertebrae since the two attachment sides are engaged with each other, thus increasing the surface area of each individual attachment side that can engage the surface of the respective spinous process, since the two attachment sides do not have to attach adjacent to each other, but overlapping such that one is attached to the top of the other. The invention provides that a single interspinous process spacing device of two attachment sides, also referred to as a pair of base plates, can be implanted alone having an integration mechanism, such as apertures therein, for future implantation of an overlapping second interspinous process spacing device of two attachment sides, also referred to as a pair of link plates.

According to one embodiment, a first interspinous process spacing device is implantable on two adjacent vertebrae by affixing to the spinous process of each vertebrae. A second interspinous process spacing device is implantable on the next adjacent vertebrae (e.g., in the superior or inferior direction) by affixing to the spinous process of the adjacent vertebrae and affixing to the adjacent end of the first interspinous process spacing device already implanted. According to one embodiment, to achieve this integrated configuration, the second (and succeeding) interspinous process spacing device has attachment sides in a bent configuration to overlap the attachment sides of the first interspinous process spacing device. The interspinous process spacing devices can include an integration mechanism, such as, but not limited to, a ball and socket arrangement or a pin and hole (aperture or slot) arrangement, or a pin and overlapping holes arrangement, or a hinge arrangement, or a bone engaging spike and hole arrangement for securely overlapping attachment sides of a first and second interspinous process spacing device and, in the case of a spiked integration mechanism, further engaging the spinous process. In various embodiments, the integration mechanism may allow for overlapping attachment sides of first and second interspinous process spacing devices without requiring a bent configuration of the attachment sides, as further described below.

Each of the interspinous process spacing devices includes a first attachment side and a second attachment side in an approximately parallel orientation relative to each other. Each of the attachment sides aligns and selectively engages a respective side of two adjacent spinous processes to retain the implant in position. Thus, the attachment sides are adjustable in a substantially perpendicular direction relative to their orientation (e.g., along the axis of the spacer tray extending between them) to permit closing and tightening them on the spinous process sandwiched therebetween. In one embodiment, the inner surfaces of each of the attachment sides include multiple fasteners (e.g., teeth, barbs, hooks, spikes, or any other gripping surface or other suitable attachment means) protruding therefrom, which interface with the surfaces of the spinous processes to facilitate attaching the attachment sides thereto. In one example, the fasteners can be positioned at or near the edges and/or corners of each attachment side to align with the spinous processes during implantation.

In one embodiment in which multiple interspinous process spacing devices are intended to be used to fasten to more than two adjacent vertebrae, the attachment sides of the first interspinous process spacing device have a substantially flat configuration, whereas the attachment sides of the second (and any subsequent) interspinous process spacing device are formed in a bent configuration, such that a portion of each attachment side is offset from the remaining portion of the attachment side to permit overlapping the first interspinous process spacing device during implantation. As such, the offset portion is set out a distance approximately equal to, or slightly larger or smaller than, the thickness of the attachment side. To improve securing the second interspinous process spacing device to the first, the outer surfaces of the attachment sides of the first interspinous process spacing device may include apertures (e.g., holes, slots, etc.) oriented to receive fasteners extending from the inner surfaces of the offset portion of the attachment sides of the second interspinous process spacing device where the two overlap. Inserting some of the fasteners of the second interspinous process spacing device into the first device increases the purchase and stability of the two devices together, improving the effectiveness of the implant. In other embodiments, however, other means for allowing an overlapping arrangement of multiple interspinous process spacing devices can be used.

In addition, according to various embodiments described herein, the interspinous process spacing devices include an improved spacer tray configured to permit increased access and provide an increased area for bone growth above the spacer tray and between the spinous processes after implant. Access to the tray space and maximized open space between the spinous processes after implant is beneficial when providing a bone growth promoting substance to fuse the spinous processes above the spacer tray. The amount and orientation of the bone material can have direct consequences on its ability to promote bone and other tissue in-growth, further strengthening the implant and its fixation to the vertebrae. By orienting the spacer tray such that it will be positioned proximate the vertebrae when implanted, bone and other tissue in-growth is improved by increasing the surface area, and the amount and proximity of the bone growth promoting substance to the vertebrae and other tissue. The spacer tray can vary in length, width and in rotatable position about an axis defined by its length.

As described, at least one attachment side of each interspinous process spacing device is configured to slide along the spacer tray to allow closing the attachment sides on the adjacent spinous processes. Each interspinous process spacing device further includes securing means to secure the attachment sides in position upon engaging the spinous processes. The securing means may vary according to different embodiments, which include, but are not limited to, worm drive mechanisms, gear and pinion mechanisms, ratchet and gear mechanisms (like a lock tie or cable tie), cam mechanisms, one or two spaced apart screws connecting the two attachment sides, any variation of the aforementioned mechanisms with only a single or multiple screw/gear/ratchet mechanisms, etc., one or more set screws, a separate clamping means combined with a set screw, or any combination thereof.

Embodiments that have at least two spaced apart securing mechanisms allow tightening each side of the interspinous process spacing device independently. As such, the attachment sides can be tightened using a “walking” approach by alternating between incremental actuations of each mechanism. Tightening each side of the interspinous process spacing device independently allows the attachment sides to close on the adjacent spinous processes in a more tight and secure configuration irrespective of varied thicknesses or shapes of the spinous processes. Otherwise, without providing independent variability when tightening each end of the attachment sides, the interspinous process spacing device may not as securely engage adjacent spinous processes having varied thicknesses. Moreover, the two spaced apart securing mechanisms may optionally avoid having to use a separate clamping and/or insertion instrument to secure the interspinous process spacing device to the spinous processes, which is required by prior devices to achieve tight fixation. However, in some embodiments described below, one may opt to use an additional insertion instrument, which may be used to provide the initial orientation and attachment or clamping of an interspinous process spacing device to the spinous processes, while the interspinous process spacing device and its integrated securing means may be used to achieve final fixation and secure engagement to the spinous processes. However, other securing mechanisms described herein that do not include two spaced apart mechanisms provide the additional advantages of a single device for securing and the unique application of mechanical securing components that tighten the two attachment sides, which simplifies the implantation procedure.

The present invention provides an interspinous process spacing device, comprising a first attachment side and a second attachment side, each attachment side comprising one or more slots formed therein and oriented proximate one end for receiving fasteners extending inwardly from a second interspinous process spacing device. The interspinous process spacing device further comprises a spacer tray positioned between the first attachment side and the second attachment side, the spacer tray extending from the first attachment side and slideably insertable through a spacer tray slot formed in the second attachment side, wherein the spacer tray is adapted to retain adjacent spinous processes in a spaced apart orientation. The interspinous process spacing device further comprises securing means for securing the second attachment side relative to the first attachment side, wherein, upon securing the second attachment side relative to the first attachment side by the securing means, the interspinous process spacing device is engaged with the adjacent spinous processes. In certain embodiments of the interspinous process spacing device, the one or more slots for receiving fasteners from a second interspinous process spacing device are oriented proximate each end of the first attachment side and the second attachment side. In certain embodiments of the interspinous process spacing device, the one or more bone fasteners extend inwardly on one end of the first attachment side and the second attachment side. In certain embodiments of the interspinous process spacing device, the one or more bone fasteners extend inwardly on each end of the first attachment side and the second attachment side.

In certain embodiments of the interspinous process spacing device, each attachment side has a central portion and two wing portions extending in opposite directions from the central portion, and the one or more bone fasteners and the one or more slots for receiving extension fasteners from a second interspinous process spacing device are located on at least one wing portion. In certain embodiments of the interspinous process spacing device, each wing portion has more than one slot for receiving extension fasteners from a second interspinous process spacing device. In certain embodiments of the interspinous process spacing device, one wing portion of the first and second attachment sides has one extension fastener extending inwardly for attaching to another interspinous process spacing device.

In certain embodiments of the interspinous process spacing device, the means for securing the second attachment side relative to the first attachment side is a bearing screw extending posteriorly through a central portion of second attachment side to the tray slot. In certain embodiments of the interspinous process spacing device, the tray slot engages the spacer tray with freedom of movement to permit at least 20 degrees of lateral rotation of the second attachment side relative to the first attachment side prior to engaging the securing means.

In certain embodiments of the interspinous process spacing device, the spacer tray comprises a T-shaped cross-section, and the tray slot in the second attachment side has a reciprocating T-shape. In certain embodiments of the interspinous process spacing device, the bottom of the T-shape is medially disposed from the first attachment side, and the cross-sectional shape tapers to a point on the spacer tray to facilitate insertion of the tray through the ligament and angled insertion of the tray through the tray slot in the second attachment side.

In certain embodiments of the interspinous process spacing device, the spacer tray has an arcuate longitudinal shape, such that the spacer tray extends in a posterior curvature to facilitate angled insertion through ligaments and into the tray slot. In certain embodiments, at least the end portion of the spacer tray extends in an arcuate shape corresponding to the arc created when the sides are attached to a pivoting insertion tool and are drawn together, as described in more detail below. In certain embodiments of the interspinous process spacing device, the spacer tray extends perpendicularly before the posterior curvature to facilitate angled insertion through the tray slot.

In certain embodiments of the interspinous process spacing device, the spacer tray comprises an arcuate cross-sectional shape such that upon implanting, the spacer tray is posteriorly open and accessible. In certain embodiments of the interspinous process spacing device, the spacer tray is adapted to retain bone growth promoting substance, wherein the bone growth promoting substance is packable after engaging the first attachment side and the second attachment side to adjacent spinous processes.

In certain embodiments of the interspinous process spacing device, the securing means for securing the second attachment side relative to the first attachment side is at least one set screw extending through the central portion from the posterior orientation to the tray slot to secure the second attachment side to the spacer tray in a substantially fixed position. In various embodiments, the securing means comprises at least one of: (a) at least one worm drive assembly; (b) at least one rack and pinion assembly; (c) at least one screw extending between and operably connecting the first attachment side and the second attachment side; (d) a geared rack and ratchet assembly; or (e) at least one set screw assembly.

In certain embodiments of the interspinous process spacing device, the securing means comprises at least two spaced apart securing mechanisms extending between and operably connecting the first attachment side and the second attachment side, wherein each of the at least two spaced apart securing mechanisms can be independently and incrementally actuated causing each end of the attachment sides to engage the respective spinous process independently.

In certain embodiments of the interspinous process spacing device, the first and second attachment side each have an insertion instrument receptacle posteriorily located on each attachment side. In certain embodiments of the interspinous process spacing device, the size, shape or indicia of the insertion instrument receptacle on the first attachment side is different from the size, shape or indicia of the implantation instrument receptacle on the second attachment side in order to facilitate connection to the correctly corresponding ends of the insertion instrument.

In certain embodiments, the interspinous process spacing device is a first interspinous process spacing device (or pair of base plates), and further comprising a second interspinous process spacing device (or pair of link plates) comprising a first offset attachment side and a second offset attachment side, wherein each offset attachment side comprises a substantially flat end and an offset end adapted to overlap over an adjacent portion of respective attachment sides of the first interspinous process spacing device and having fasteners extending inwardly therefrom receivable into the slots in each attachment side of the first interspinous process spacing device.

In certain embodiments of the interspinous process spacing device, the substantially flat end further comprises one or more bone fasteners extending inwardly and one or more slots formed therein for receiving fasteners extending inwardly from a third interspinous process spacing device. In certain embodiments of the interspinous process spacing device, the first attachment side and the second attachment side of the second interspinous process spacing device each have an integration means for integrating and attaching the offset end of the second interspinous process spacing device with a portion of the respective attachment side of the first interspinous process spacing device.

In certain embodiments of the interspinous process spacing device, the integration means comprise fasteners extending inwardly from the second interspinous process spacing device which pivotally engage the one or more slots formed in each attachment side of the first interspinous process spacing device, such that the second interspinous process spacing device can pivot through a 155 degree angle with respect to the first interspinous process spacing device. In certain embodiments of the interspinous process spacing device, the second interspinous process spacing device can pivot through a 120 degree angle with respect to the first interspinous process spacing device. In certain embodiments of the interspinous process spacing device, the second interspinous process spacing device can pivot posteriorly and anteriorly through substantially equal degrees with respect to the first interspinous process spacing device.

In certain embodiments of the interspinous process spacing device, the integration means comprises at least one of: (a) one or more fasteners extending from the inner surfaces of the offset end and receivable by the one or more apertures formed in the respective attachment side of the first interspinous process spacing device; (b) at least one pin extending from the inner surfaces of the offset end and receivable by the one or more apertures formed in the respective attachment side of the first interspinous process spacing device; (c) a domed surface extending from the inner surface of the offset end and receivable by a dome-shaped recess formed in the respective attachment side of the first interspinous process spacing device; (d) a textured surface formed on the inner surface of the offset end and mateable to a textured surface formed on the outer surface of the respective attachment side of the first interspinous process spacing device; or (e) a textured domed surface extending from the inner surface of the offset end and receivable by a complementarily-shaped textured recess formed in the respective attachment side of the first interspinous process spacing device.

In certain embodiments of the interspinous process spacing device, the offset ends of the second interspinous process spacing device are offset by a distance approximately equal to the thickness of the respective attachment side of the first interspinous process spacing device. In certain embodiments of the interspinous process spacing device, the first interspinous process spacing device is implantable at an inferior position relative to the second interspinous process spacing device. In certain embodiments of the interspinous process spacing device, the first interspinous process spacing device is implantable at a superior position relative to the second interspinous process spacing device.

In certain embodiments, the interspinous process spacing device is configured for implantation at the L5-S1 vertebrae and comprising a first angled attachment side and a second angled attachment side, wherein each angled attachment side comprises an angled end adapted to accommodate a sacrum. In certain embodiments, the first and second angled attachment sides are each selectively adjustable for optimizing the angle to fit the particular patient's sacrum anatomy and then securing the selected angle. The ends opposite the angled sacrum attachment ends can have bone fasteners extending from the inner surfaces thereof and one or more apertures therethrough, allowing the device to serve as a base plate for receiving fasteners on a second superiorly located spacing device. Alternatively, the ends opposite the angled sacrum attachment ends can be offset and each have a fastener (such as a bone fastening spike) extending from the inner surfaces thereof, allowing the device to serve as a link plate to be received within one or more apertures in a second superiorly located spacing device. Both embodiments permit rotational optimization of the relative angle between the first and second spacing devices to fit the patient's anatomy. In certain embodiments of the interspinous process spacing device, the angled end of each angled attachment side of the interspinous process spacing device further comprises one or more angled fasteners extending from the inner surface at an angle other than ninety degrees and adapted for engaging the sacrum.

In certain embodiments of the interspinous process spacing device, each attachment side has a central portion and two wing portions extending in opposite directions from the central portion superiorly and inferiorly, and the inferior wings each have the angled end adapted to accommodate a sacrum and have one or more bone fasteners extending inwardly therefrom, and the superior wings each have one or more slots formed therein for receiving extension fasteners from a second interspinous process spacing device.

In certain embodiments of the interspinous process spacing device, the superior wings each have one or more bone fasteners extending inwardly therefrom. In certain embodiments of the interspinous process spacing device, the superior wings each have an extension fastener extending inwardly for attaching to another interspinous process spacing device. In certain embodiments of the interspinous process spacing device, the bone fasteners on the inferior wings each comprise a bone screw or movable spike or an axially expandable spike to engage the bone disposed through the wing. In certain embodiments of the interspinous process spacing device, the bone fasteners on the inferior wings further comprise one or more stationary spikes extending inwardly therefrom at angle different than an angle at which the bone screw or movable spike is disposed through the wing.

In certain embodiments of the interspinous process spacing device, the superior wings each have more than one slot formed therein for receiving fasteners extending inwardly from a second interspinous process spacing device. In certain embodiments of the interspinous process spacing device, the superior wings permit a fastened second interspinous process spacing device to pivot up to a 155 degree or a 60 degree angle with respect to the interspinous process device for implantation on the sacrum at the L5-S1 vertebrae.

The present invention further provides an interspinous process spacing system, comprising a first interspinous process spacing device and a second interspinous process spacing device, wherein the first interspinous process spacing device comprises two substantially flat attachment sides and a first spacer tray positioned therebetween, wherein one of the two substantially flat attachment sides is slideably positionable over the spacer tray. In certain embodiments of the interspinous process spacing device, wherein the second interspinous process spacing device comprises two offset attachment sides and a second spacer tray positioned therebetween, each of the offset attachment sides comprises a substantially flat end and an offset end.

The invention provides in certain embodiments that after implantation of the first interspinous process spacing device on a first and a second adjacent spinous process, the offset ends of the two offset attachment sides of the second interspinous process spacing device at least partially overlap respective adjacent ends of the substantially flat attachment sides of the first interspinous process spacing device when implanting the second interspinous process spacing device on the second and a third spinous process adjacent to the second spinous process.

In certain embodiments of the interspinous process spacing device, each of the offset ends of the two offset attachment sides comprises an integration means for integrating and attaching the offset end of the second interspinous process spacing device with a portion of the respective attachment side of the first interspinous process spacing device when overlapping.

In certain embodiments of the interspinous process spacing device, the integration means comprise fasteners extending inwardly from the second interspinous process spacing device which pivotally engage the one or more slots formed in each attachment side of the first interspinous process spacing device, such that the second interspinous process spacing device can pivot through a 155 degree angle with respect to the first interspinous process spacing device.

In certain embodiments of the interspinous process spacing device, each of the substantially flat attachment sides and the offset attachment sides comprises one or more bone fasteners extending from the inner surface for engaging respective spinous processes when implanted. In certain embodiments of the interspinous process spacing device, the substantially flat end on each of the offset attachment sides of the second interspinous process spacing device comprises one or more slots formed in an outer surface for receiving one or more fasteners extending from an inner surface of a respective offset attachment side of a third interspinous process spacing device adapted to overlap the substantially flat ends of the second interspinous process spacing device.

In certain embodiments the invention provides an interspinous process spacing device kit comprising: a first interspinous process spacing device comprising a first attachment side and a second attachment side, the first and the second attachment sides of the first interspinous process spacing device having a substantially flat configuration; a second interspinous process spacing device comprising a first attachment side and a second attachment side, the first and the second attachment sides of the second interspinous process spacing device having an offset configuration adapted to overlap a portion of a respective attachment side of the first interspinous process spacing device; and at least one insertion instrument adapted for retaining at least one of the first interspinous processing spacing devices or the at least one additional interspinous process spacing device and implanting the same.

In certain embodiments of the interspinous process spacing device, each interspinous process spacing device further comprises a spacer tray positioned between the first attachment side and the second attachment side, the spacer tray having a width and length extending from the first attachment side and slideably insertable through a tray slot formed in the second attachment side, wherein the spacer tray is adapted to retain adjacent spinous processes in a spaced apart orientation, and wherein the kit further comprises a plurality of alternatively sized first and second interspinous process spacing devices having different spacer tray widths.

The present invention further provides a surgical instrument system for implanting an interspinous process spacing device, comprising a means for positioning a first arm and a second arm in alignment for securing the interspinous process spacing device onto spinal processes. In certain embodiments of the surgical instrument system for implanting an interspinous process spacing device, the proximal and distal ends are offset to provide an unobstructed view of the distal ends when holding the proximal ends. In certain embodiments, each arm permits an engaged attachment side of the interspinous process spacing device at least 5 degrees, or at least 10 degrees, and up to 30 degrees, of rotation about an axis defined by the engagement element on the distal end of the arm. In certain embodiments of the surgical instrument system for implanting an interspinous process spacing device, the engagement element comprises an engagement projection which releasably engages an instrument receptacle on the attachment side of the interspinous process spacing device, a mount for movably holding the engagement projection, and an implant guide extending distally past the engagement projection which engages an outer surface of an engaged attachment side of the interspinous process spacing device.

In certain embodiments of the surgical instrument system for implanting an interspinous process spacing device, the engagement projection on the second arm provides access to a securing means on the second attachment side of the interspinous process spacing device to secure the second side to the first side. In certain embodiments, the engagement projection is a threaded screw which engages a reciprocal threaded instrument receptacle instrument on the attachment side of the interspinous process spacing device. In certain embodiments, the threaded screw on the second arm is cannulated to provide access therethrough to a securing means on the second attachment side of the interspinous process spacing device to secure the second side to the first side while the second side is engaged to the second arm.

In certain embodiments of the surgical instrument system for implanting an interspinous process spacing device, the size, shape or indicia of the insertion instrument receptacle on the first attachment side is different from the size, shape or indicia of the insertion instrument receptacle on the second attachment side to facilitate connection to the correctly corresponding ends of the insertion instrument.

In certain embodiments of the surgical instrument system for implanting an interspinous process spacing device, the proximal ends of the first and second arms are releasably connectable at more than one selected distance. In certain embodiments of the surgical instrument system for implanting an interspinous process spacing device, the central portions of the first and second arms are releasably and rotatably connectable.

In certain embodiments, the present invention provides a top-down surgical instrument system for implanting an interspinous process spacing device, comprising a first arm having a proximal end, an elongated central portion and distal end, wherein the distal end has an interspinous process spacing device engagement element for posteriorly engaging a first attachment side of the interspinous process spacing device having a spacer tray extending inwardly therefrom. Certain embodiments comprise a second arm having a proximal end, an elongated central portion and distal end, wherein the distal end has an interspinous process spacing device engagement element for posteriorly engaging a second attachment side of the interspinous process spacing device having a spacer tray slot therein for receiving the spacer tray. In such embodiments, the second arm is removably and pivotally attachable to the first arm about an axis for positioning the first arm and the second arm in alignment for securing the interspinous process spacing device onto spinal processes.

In certain embodiments of the surgical instrument system for implanting an interspinous process spacing device, the second arm further comprises a pivot member or pin located on the central portion and the first arm further comprises a pivot channel or slot with a proximally oriented opening and a distally oriented curved retaining edge, such when the pin is slideably engaged in the slot against the retaining edge the first and second arms are removeably and pivotally attached to form a hinge, wherein the hinge permits positioning the first arm and the second arm in alignment for securing the interspinous process spacing device onto spinal processes.

In certain embodiments of the surgical instrument system for implanting an interspinous process spacing device, when the first and second arms each have a respective first and second attachment side of the interspinous process spacing device engaged thereto, and the first and second arms are attached at the hinge, drawing the proximal ends of the arms together will align and insert the spacer tray into the spacer tray slot of the first and second attachment sides of the interspinous process spacing device for securing the interspinous process spacing device onto spinal processes.

In certain embodiments of the surgical instrument system for implanting an interspinous process spacing device, the first arm further comprises a releasable locking mechanism for selectively securing the pin of the second arm into the slot of the first arm. In certain embodiments, the releasable locking mechanism is a leaf spring on the central portion of the first arm in blocking communication with the slot, such that the pin on the second arm can deflect the leaf spring during insertion into the slot and remain therein when the leaf spring returns to blocking communication to maintain the pin against the retaining edge on the first arm, and wherein the leaf spring can be manually disengaged from blocking communication with the slot to release the pin and separate the first and second arms.

In certain embodiments of the surgical instrument system for implanting an interspinous process spacing device, the surgical instrument comprises means for mechanically actuating the insertion instrument to close and open the first arm and the second arm for tightening the second attachment side relative to the first attachment side. In certain embodiments, the means for mechanically actuating is a ratchet bar pivotally mounted to the proximal end of the second arm and selectively engageable to the proximal end of the first arm, wherein the ratchet bar has a plurality of teeth on the proximal surface thereof which engage a corresponding flange on the proximal end of the first arm.

In certain embodiments of the surgical instrument system for implanting an interspinous process spacing device, the ratchet bar has one or more indicators of predetermined length corresponding to space between the mounted sides of the interspinous process spacing device. In certain embodiments, the ratchet bar further comprises a threaded track and a nut riding thereon outside the proximal end of the first arm for mechanically forcing the proximal ends of the arms together.

The present invention further provides a surgical instrument system for implanting an interspinous process spacing device, comprising a first arm having a proximal end, an elongated central portion and distal end, wherein the distal end has an interspinous process spacing device engagement element for posteriorly engaging a first attachment side of the interspinous process spacing device having a spacer tray extending inwardly therefrom. Such an embodiment also comprises a second arm having a proximal end, an elongated central portion and distal end, wherein the distal end has an interspinous process spacing device engagement element for posteriorly engaging a second attachment side of the interspinous process spacing device having a spacer tray slot therein for receiving the spacer tray. This embodiment can further be used with a compressor tool for positioning the first arm and the second arm in alignment for securing the interspinous process spacing device onto spinal processes.

In certain embodiments of the surgical instrument system for implanting an interspinous process spacing device, the compressor tool has a proximal handle end a central portion and a distal pair of opposing tangs moveable throughout a range between an open position and a compression position. In certain embodiments, the distal end of each arm comprises compressor tool guide channels and compression point indentations therein for receiving the compressor tool tangs. The compression points permit delivery of substantially equal amounts of pressure across each attachment side of the plate, allowing less invasive surgical implantation with a single compressor tool than would be required with multiple compression points and multiple compression tools. In certain embodiments, the tangs have distal compressor tips extending inwardly for engagement within the corresponding guide channels and compression point indentations on the arms, wherein the compression tool can rotate about an axis defined by the compressor tips so as to provide a user with a range of approach angles and approach from either side of the implantation tool and compress the arms to secure the aligned interspinous process spacing device onto spinal processes.

In certain embodiments of the surgical instrument system for implanting an interspinous process spacing device, the proximal end of one arm further comprises a retaining latch disposable on the distal end of the other arm to retain the arms in position relative to each other and in alignment for securing the interspinous process spacing device onto spinal processes.

In certain embodiments of the surgical instrument system for implanting an interspinous process spacing device, the surgical instrument comprises means for mechanically actuating the insertion instrument to close and open the first arm and the second arm for tightening the second attachment side relative to the first attachment side. In certain embodiments, the means for mechanically actuating is a ratchet bar pivotally mounted to the proximal end of the second arm and selectively engageable to the proximal end of the first arm, wherein the ratchet bar has a plurality of teeth on the proximal surface thereof which engage a corresponding flange on the proximal end of the first arm. In certain embodiments, the ratchet bar has one or more indicators of predetermined length corresponding to space between the mounted sides of the interspinous process spacing device. In certain embodiments, the ratchet bar further comprises a threaded track and a nut riding thereon outside the proximal end of the first arm for mechanically forcing the proximal ends of the arms together.

The present invention also provides a surgical instrument for selecting an interspinous process spacing device. In certain embodiments, the selection instrument comprises a first arm having a proximal end, an elongated central portion and distal end, wherein the distal end has a first interspinous process spacing measurement wing extending therefrom comprising a first spinous process stop element and a perpendicular wing template, and a second arm having a proximal end, an elongated central portion and distal end, wherein the distal end has a second interspinous process spacing measurement wing extending therefrom comprising a second spinous process stop element and a perpendicular wing template. In certain embodiments of the surgical instrument, the first and second arms are pivotally attached about an axis for positioning the first and second interspinous process spacing measurement wings to measure space between adjacent spinal processes. The instrument also allows for selection of an adjacent base plate or link plate superior or inferior to the existing implanted plate.

In certain embodiments of the surgical instrument, the measurement device can further comprise first and second wing templates adapted to overlap respective first and second adjacent spinal processes to determine space available on each spinous process for engaging an interspinous process implant. In certain embodiments, the instrument determines the space available for implantation of either a base plate device or an overlapping link plate device. In certain embodiments, the instrument can be adapted such that the proximal end of the first or second arm has a measuring element attached thereto with indicia to register length to the proximal end of the other arm, wherein said length corresponds to space between adjacent spinal processes as measured by the first and second spinous process stop elements. In certain embodiments of the surgical instrument, drawing the proximal ends of the arms together separates the wings to measure space between adjacent spinal processes. In one embodiment, the first or second wing template, or both, comprises a fastener template extending therefrom adapted to engage with a slot on an attachment side of an interspinous process spacing device previously implanted to determine space and orientation available for overlapping engagement of a link plate onto a base plate.

Example embodiments of interspinous process spacing devices are further described with reference to the FIGS. 1-12. Extending posteriorly from each vertebra are spinous processes. Laminae connect the spinous processes to respective transverse processes. Facet joints between the processes of adjacent vertebrae guide articulation of the vertebrae. Interspinous process spacing devices as described herein may be implanted between adjacent spinous processes of any of the cervical, thoracic, and/or lumbar vertebrae.

As shown in FIG. 1 are three engaged interspinous process spacing devices—a first base plate type interspinous process spacing device 130, a second link plate type interspinous process spacing device 132 overlapping the superior end of the first interspinous process spacing device 130, and a third link plate type interspinous process spacing device 134 overlapping the inferior end of the first interspinous process spacing device 130. The first interspinous process spacing device 130 includes a first attachment side 140 and a second attachment side 142, engaging either side of the adjacent spinous processes. Similarly, the second and third interspinous process spacing devices 132, 134 include a first attachment side 144 and a second attachment side 146. According to this embodiment, the attachment sides 144, 146 of the second interspinous process spacing device have an offset configuration to permit overlap with the first interspinous process spacing device 130. Thus, each of the first and second attachment sides 144, 146 of the second and third interspinous process spacing devices 132, 134 has a substantially flat end 148 and an offset end 149, with the offset being approximately the anticipated thickness of the first or second attachment side 140, 142 of the first interspinous process spacing device 130 (or a slight variation thereof), which is described and illustrated in more detail with reference to FIGS. 2-4.

According to various embodiments, the size and dimension of the first and the second attachment sides 140, 142, 144, 146 may vary according to the intended use of the interspinous process spacing devices 130, 132 which may vary based at least in part on the intended implant location on the spine, the patient size, the treatment, and the like. For example, attachment sides may vary in length and/or height to accommodate the varying sizes of spinous processes. Moreover, as described below with reference to FIGS. 5A-5C and 7A-7E, attachment side geometry may be adapted for implanting at specific locations of a spine that require different configurations, such as at the L5-S1 vertebrae.

Similarly, spacer tray dimensions, as described below, may also vary in size, such as to accommodate varying patient and/or implant location anatomy. In one example, the spacer tray may have a substantially smaller width than is illustrated in FIG. 1, which may facilitate insertion through the ligaments existing between the spinous processes. Kits including interspinous process spacing devices with a range of spacer tray widths to select from are provided, such as shown in FIG. 6A-6B. In certain embodiments, the spacer tray widths can be provided in increments ranging from less than or 8 mm, 10 mm, 12 mm, 14 mm, 16 mm, to 18 mm, or more, such as shown in FIGS. 6A-6B. Example spacer tray lengths can be 10 mm to 30 mm, or 23.4 mm. In another example, an interspinous process spacing device may not include a spacer tray. A spacer tray selection instrument is also provided and is described in more detail below with reference to FIGS. 21A and 21B.

In certain example embodiments, the width of the wings on a base and link plate, such as shown in FIGS. 2-3 can be 3 mm, the width of the central portion of the first attachment side can be 6 mm, and the width of the central portion of the second attachment side can be 8.5 mm. An exemplary height for the base plate and link plate attachment sides is 18 mm.

In certain example embodiments, the length of the wings on either side of the spacer tray can be 10.5 mm for a first interspinous process device base plate and 12.5 mm for a second interspinous process device link plate. Therefore, for an example device with a 8 mm spacer tray width, the total plate length for a base plate would be 29 mm, and for a link plate would be 31 mm.

Each of the interspinous process spacing devices 130, 132 may include a spacer tray 150 extending between attachment sides 140, 142 and 144, 146, respectively. The spacer tray 150 is configured with surfaces to abut the spinous processes to maintain the spaced apart relationship of the spinous processes. According to various embodiments, as illustrated in FIGS. 1-12, the spacer tray 150 may have a substantially open configuration that is accessible from the posterior direction, which serves to maximize the surface area for bone growth promoting substances. Access from the posterior direction allows the surgeon to insert the bone growth promoting substance (or any other material to facilitate bone in-growth, structural support, and/or healing) after implanting the interspinous process spacing devices. Otherwise, without posterior access, the bone growth promoting substance must be inserted prior to implantation, which likely will not result in the most effective placement and/or quantity of bone growth promoting substance. In contrast to conventional interspinous spacers, which typically have a circular cross-section and occupy a substantial area between adjacent spinous processes, the spacer tray 150 described herein has a reduced cross-sectional profile and a tapered width on the leading front edge, which eases insertion between the ligaments occupying the space between adjacent spinous processes. The conventional devices often require significant retraction and/or cutting of the ligaments to implant a device because the larger, circular cross-section of the components existing between the sides cannot easily be inserted between the ligaments, increasing the difficulty, risk, and healing time of the implant procedure.

Accordingly, the spacer tray 150 described herein can be inserted between the ligaments without cutting due to its reduced, tapered, or flattened profile compared to the larger, circular cross-sections of other devices. However, in other embodiments, the spacer tray 150 may be configured in a variety of shapes and sizes to accommodate anatomical variation among patients and intended treatment and space correction, and to accommodate the positioning of a securing mechanism, as further described below. The spacer tray 150 may further optionally include apertures through the spacer tray 150, which act to facilitate bone and tissue in-growth by maximizing the available surface area from the adjacent spinous processes and cause further fusion thereof. These and other features and variations thereof are discussed in more detail with reference to the following FIGS. 2-12.

Moreover, according to another embodiment, the spacer tray 150 may have a minimized width to increase the ease of insertion and to occupy less space between adjacent spinous processes. In fact, in one embodiment a spacer tray may not be included at all, and alignment, connection, and stability between the two attachment sides 140, 142 may be accomplished by way of the securing means, such as those described with reference to FIGS. 8 and 10. In this embodiment, the securing means may further serve to absorb impact from, and to limit movement of, one or more of the adjacent spinous processes, which otherwise would be achieved by a spacer tray.

FIGS. 2-7 show details of interspinous process spacing devices according to one embodiment, such as the first interspinous process spacing device 130 (as illustrated in FIG. 1). FIGS. 6-9 show example spacer tray 150 configurations, according to various example embodiments. The first attachment side 140 includes a spacer tray 150 extending in a substantially perpendicular direction from the first attachment side 140. The spacer tray 150 shown is configured to have a substantially arcuate cross-sectional shape, permitting access to the tray after implanting the interspinous process spacing device 130. However, the spacer tray may have any cross-sectional shape, such as, but not limited to, flat, angled, a partial square, a partial hexagon, a partial octagon, a T-shape, a cross shape, and the like, such as, but not limited to, those illustrated by example in FIGS. 1-12. The dimensions of the spacer tray 150 can depend upon the desired level of movement and/or size of the desired space to be retained between the two adjacent spinous processes. The spacer tray 150 may further optionally include chambers formed through the tray, which may be oriented to provide additional clearance of the spacer tray 150 from posteriorly facing bone surfaces (e.g., spinous processes, facet joints, etc.). Accordingly, a spacer tray 150 acts to maintain a minimum distance between adjacent spinous processes to move the vertebrae apart and relieve pressure on nerve tissue and/or facet joints.

The cross-sectional shape of the spacer tray 150 can facilitate insertion into the tray slot 210. For example, as shown in FIGS. 2-7, the T-shaped cross-section, with the bottom of the T extending medially or downward into the spine provides a supporting lift for the tip of the spacer tray off of the vertebrae and into the tray slot. Similarly, the tapering cross-section of the tip of the spacer tray into a rounded point facilitates insertion into the slot, as well as facilitating insertion through the ligaments existing between the spinous processes. Finally, the arcuate longitudinal cross-section facilitates insertion when both sides are engaged with an insertion tool and being drawn together in an arc, as described below.

Moreover, the spacer tray 150 is shaped to permit access from the posterior direction, which increases the ease with which bone growth promoting substance is placed above the spacer tray 150 and proximate the vertebrae, while also increasing the available spinous process surface area. In some embodiments, bone growth promoting substance can be inserted in or near other areas of the interspinous process spacing device. Also as illustrated in FIGS. 9B-9D, the spacer tray 150 can optionally include tray apertures 320 or other openings extending through the spacer tray 150 to further facilitate tissue and/or bone in-growth. Any number of tray apertures 320 may be included in any size, shape, or configuration. As used herein, bone growth promoting substance may include, but is not limited to, bone paste, bone chips, bone strips, structural bone grafts, platelet-derived growth factors, bone marrow aspirate, stem cells, bone growth proteins, bone growth peptides, bone attachment proteins, bone attachment peptides, hydroxylapatite, calcium phosphate, and/or other suitable bone growth promoting substances.

The second attachment side 142 includes a tray slot 210 having a similar shape as the spacer tray 150 to permit the spacer tray 150 to slide therethrough. Accordingly, the second attachment side 142 is slideably adjustable along the axis of the spacer tray 150 so the second attachment side 142 can move toward the first attachment side 140 when tightening to allow the attachment sides 140, 142 to be positioned along either side of, and secured to, the spinous processes. It is appreciated that in other embodiments, the spacer tray may extend from the second attachment side and slideably pass through the first attachment side, and that the orientation relative to the patient's spine may vary from that described and illustrated herein.

According to one embodiment, as is shown in more detail with reference to FIG. 4 and FIG. 6 (a simplified perspective view of an interspinous process spacing device), the tray slot 210 is sized slightly larger than the cross-section area of the spacer tray 150 to provide loose fitting of the second attachment side 142 over the spacer tray 150, permitting at least slight angular movement of the second attachment side 142 relative to the first attachment side 140, but providing enough constraint so as to retain the approximate orientation of the second attachment side 142 relative to the spacer tray 150. As a result of this slight angular variation allowed, opposite ends of the attachment sides can be tightened independently and can adapt to adjacent spinous processes having varied thicknesses (e.g., permitting the attachment sides to close tighter or narrower on one end relative to the other, such as if one spinous process is smaller or narrower than the other). The size of the tray slot 210 relative to the spacer tray 150 may vary according to the desired level of angular variation of the second attachment side 142 relative to the first attachment side 140. In other embodiments, however, the tray slot 210 may form a tight fit around the spacer tray 150 to prevent significant angular variation or other movement of the second attachment side 142 relative to the spacer tray 150. The fit between the tray slot 210 and the spacer tray 150 further serves to absorb torque or any other force applied by the spacer tray 150 against the second attachment side 142, providing increased stability of the attachment sides 140, 142 relative to each other and against the patient's spinous processes when implanted.

In certain embodiments of the interspinous process spacing device, the tray slot engages the spacer tray with freedom of movement to permit at least 20 degrees of lateral rotation of the second attachment side relative to the first attachment side prior to engaging the securing means. However, in other embodiments, the tray slot 210 may form a more secure fit with the spacer tray 150, preventing significant angular movement therein. For example, in embodiments in which the securing mechanism utilizes a gearing mechanism, a tighter fit may serve to prevent cross-threading or poor meshing of the gearing mechanisms.

Also illustrated in FIGS. 2-7 are fasteners 220 extending from the inner surfaces of each of the attachment sides 140, 142. The fasteners 220 improve the ability of the attachment sides 140, 142 to engage the spinous processes and/or serve as an integration means to engage the exterior surface of the adjacent interspinous process spacing device, such as is illustrated in and described with reference to FIGS. 5A-5C. In certain embodiments of the interspinous process spacing device, the integration means comprise fasteners extending inwardly from the second interspinous process spacing device which pivotally engage the one or more slots formed in each attachment side of the first interspinous process spacing device, such that the second interspinous process spacing device can pivot through a 155 degree angle with respect to the first interspinous process spacing device. In certain embodiments of the interspinous process spacing device, the second interspinous process spacing device can pivot through a 60 degree angle with respect to the first interspinous process spacing device. In certain embodiments of the interspinous process spacing device, such as illustrated in FIGS. 5A-5B, where multiple apertures are provided for the fastener, and where multiple apertures partially overlap as illustrated in FIG. 5C, the second interspinous process spacing device can pivot through a range of angles with respect to the first interspinous process spacing device. It is understood that the device can be configured for pivotal rotation of the first interspinous process spacing device relative to the second interspinous process spacing device through any range of degrees desired including for example 180, 170, 160, 155, 150, 140, 130, 120, 110, 100, 90, 80, 70, 60, 50, 40, 30, 20, 10, 5 and 0 degrees. In certain embodiments of the interspinous process spacing device, the second interspinous process spacing device can pivot posteriorly and anteriorly through substantially equal or unequal degrees in each direction with respect to the first interspinous process spacing device.

The fasteners 220 illustrated in FIGS. 2-7 are shown as teeth or barbs, but any other fastening or other securing mechanism may be used, including, but not limited to, pins, hooks, wires, spikes, straps, clamps, sutures, adhesives, or any other suitable fastening mechanism. Moreover, according to various embodiments, the fasteners 220 may be interchangeable with other types of fastening mechanisms and/or may be adjustable to accommodate varying anatomy among patients. In addition to, or in lieu of, the fasteners 220 shown in FIGS. 2-7, other integration means may be provided that facilitate the integration of and securement between two adjacent interspinous process spacing devices when implanted in an overlapping configuration.

In the embodiments shown in FIGS. 1-7, the fasteners 220 are projecting inward from second link plates 144,146 of the second interspinous process spacing device toward slots 315 in base plates 140,142 of the first interspinous process spacing device to pivotally engage the two devices together prior to further securing with securing means 230 which is in this embodiment a set or bearing screw. Bone fastening members 225 are shown on the inner surfaces of the plates. In certain embodiments, the bone fastening members alternately extend from each opposing plate to different points on the spinous process to minimize the potential for fracture by bearing directly on opposing sides of the bone. Examples of these and other integration members are illustrated in and described with reference to FIGS. 1-12.

Example securing means 230 are particularly illustrated by FIG. 4 with set screw extending through the central portion of the second attachment side 142 onto the spacer tray 150 in the tray slot 210. Various additional example embodiments illustrated and described in more detail with reference to FIG. 8. The securing means 230 illustrated in FIG. 8 includes two spaced apart screws 310 extending between the attachment sides 140, 142 and oriented substantially along the same axis as the spacer tray 150. In the embodiment illustrated in FIG. 8, the screws 310 extend through the second attachment side 142 through apertures 312 and are received by the complementary threaded collars 314 extending from the inner surface of the first attachment side 140. However, it is appreciated that the screws 310 may instead pass through the first attachment side 140 and be received by collars on the second attachment side 142 in other embodiments. According to one embodiment, the threaded collars 314 extend a given distance from the inner surface of the first attachment side 140 so as to permit receiving the respective screws 310 while the attachment sides 140, 142 are still sufficiently separated, and to reduce the length of the screws 310. The distance the threaded collars 314 extend may vary, but can be determined to extend the maximum distance without interfering with the vertebrae, other components of the interspinous process spacing device, and/or access to spacer tray 150 to provide bone growth promoting substance therein. Similarly, the orientation of the securing means 230 is chosen to avoid interfering with the vertebrae (e.g., the spinous process) during implantation, while also providing maximum securing and purchase strength of the attachment sides 140, 142 to the spinous process. In another example, one or more screws 310 can be positioned between the space of a spacer tray 150 formed from multiple members and creating a space therein.

Spaced apart screws (or other securing means, as described in more detail below) permit independently adjusting opposite ends of the attachment sides 140, 142 and thus independently securing opposite ends of the attachment sides 140, 142 to the respective spinous process. For example, during tightening, the superior screw can be incrementally tightened, then the inferior screw can be incrementally tightened, and so forth until each end of the attachment sides 140, 142 is secured to the respective spinous process. This method allows tightening the interspinous process spacing device by “walking” opposite ends, and thus accounting for varied thicknesses of adjacent spinous processes. Additional embodiments including spaced apart screws or similar spaced apart securing means are described with reference to FIGS. 8A-8D.

Moreover, some example securing means described herein may generally avoid having to use a separate clamping and/or insertion instrument. By tightening the screws 310, the attachment sides 140, 142 close on the spinous processes without any additional clamping or tightening force. However, other securing means described herein can be implanted using an insertion instrument to facilitate retaining desired positioning of the interspinous process spacing device and/or to tighten the attachment sides 140, 142 against the spinous processes. In certain embodiments, the insertion instrument can also aid in aligning and engaging the two attachment sides of the device without requiring removal of the spinous process ligament. For example, the device embodiments described may be used to initially insert and position an interspinous process spacing device, while the securing means of the interspinous process spacing device may be used to achieve final fixation to the spinous processes. Though, in other embodiments, a clamping and/or insertion instrument may have an integrated tightening means (e.g., geared, ratchet, lever, etc.) that facilitates securing an interspinous process spacing device to the spine by tightening the clamping instrument, while the securing means of the interspinous process spacing device serve to secure and retain the device in tightened configuration.

Additional securing means embodiments are illustrated in FIG. 8 and FIG. 10. FIG. 8B illustrates the securing means as described, incorporating two spaced apart screws 310 passing through apertures 312 in the second attachment side 142 and threadably received by collars 314 in the first attachment side 140. In this embodiment, the screws 310 are positioned posterior from the spacer tray 150 and substantially within the diameter of the spacer tray 150, to avoid interference with the vertebrae upon implant. However, any other locations may be used as desired. In addition, according to other embodiments, more than two screws can be used, or only one screw can be used.

FIG. 8C illustrates another embodiment of a securing means used to tighten the opposing attachment sides 140, 142 on adjacent spinous processes. In this embodiment, two spaced apart worm drive mechanisms include two screws 410 (i.e., the worms) passing through two apertures 412 in the second attachment side 142 and operably engaging worm gearing 414. The worm drive mechanisms are adapted to provide movement along the axis of the spacer tray 150 as a result of the rotational forces applied to screws 410 that are transferred to the adapted worm gearing 414. In this embodiment, instead of a traditional worm gear, a portion of the inner surfaces are toothed complementary to the screws 410. Thus, when the screws 410 operably engage the teeth of the worm gearing 414 on the surface of the spacer tray 150, the screws' 410 threading passes along the worm gearing and causes the second attachment side 142 to move along the spacer tray 150. It is appreciated that, in other embodiments, the worm gearing 414 may be on any other surface of the spacer tray 150, or worm gearing separate from the spacer tray 150 may be provided. For example, in one embodiment, one or more screws (e.g., the worms) may rotatably extend through the inner surface of the first attachment side 140 and extend through apertures in the second attachment side 142. In this configuration, which is essentially reversed from the above-described worm drive mechanism, the worm screw extending along the axis of the spacer tray 150 is turned against a worm gear rotatably affixed to one of the attachment sides 140, 142, causing the second attachment side 142 to move along the screws. Again, in any of these embodiments, two spaced apart worm drive mechanisms permit the independent tightening, and thus the “walking” effect when closing the attachment sides 140, 142 on the spinous processes.

FIG. 8D illustrates a side view of another embodiment of a securing means used to tighten opposing attachment sides 140, 142 onto adjacent spinous processes. According to this embodiment, two spur gear mechanisms include gearing teeth 420 formed on the inner or outer surfaces of the spacer tray 150, much like that described with reference to FIG. 8C, and a shaft and gear 422 rotatably affixed to the outer surface of the second attachment side 142 that meshes with the gearing teeth 420 of the spacer tray. This embodiment behaves similar to a rack and pinion, whereby the gearing teeth 420 serve as a rack and the shaft and gear 422 serve as the pinion. Accordingly, turning each of the shaft and gears 422 causes the gears to operably mesh with the gearing teeth 420 and close the second attachment side 142 toward the first attachment side 140. It is appreciated that, in one embodiment of a spur gear mechanism (or any other securing means embodiments described herein), the shaft and gears can include a one-way or reverse lock-out mechanism to only permit rotation or movement in one direction—that which results in tightening the attachment sides together, but restricts movement in the opposite direction. In some embodiments, the one-way or reverse lock-out mechanisms may be selectively actuated, such that an operator may release them (e.g., to reposition the device, to remove the device, etc.).

According to another embodiment, a mechanism configured in a manner similar to a rack and pinion is used. Instead of the gearing being integrated with a spacer tray, this embodiment includes a separate geared rack extending from the first attachment side 140 and slideably positioned within an aperture formed in the second attachment side 142. The aperture can be sized to permit the geared rack to slide within the aperture. Also integrated or adapted with the second attachment side 142 is a shaft and gear that meshes with the geared rack. This embodiment behaves similar to a rack and pinion, whereby the shaft and gear serve as the pinion for the geared rack, advancing the second attachment side 142 along the geared rack when the shaft and gear is turned, rotated, or otherwise actuated. Any one-way or reverse lock-out mechanism to permit rotation or movement in only one direction optionally can be incorporated in the securing means embodiment. In one embodiment, the gearing on both the geared rack 440 and the shaft and gear are complementarily angled with respect to each other, which serves to hold the position of the shaft end gear against the geared rack when tightened and resists backing out or otherwise loosening by the attachment sides 140, 142 when secured in place.

In one embodiment the fit of the geared rack within the aperture is a relatively tight fit to reduce angular movement of the second attachment side 142 relative to the geared rack, which may serve to reduce the potential of cross-threading or otherwise preventing meshing of the shaft end gear with the geared rack. In other embodiments, however, the fit may be looser, allowing at least partial angular movement of the second attachment side 142 relative to the geared rack. A looser fit may be used to allow the attachment sides 140, 142 to be positioned at an angle (i.e., not exactly parallel to each other) to account for differences in the width of adjacent spinous processes.

FIG. 10 illustrates another embodiment of a securing means used to tighten the opposing attachment sides 140, 142 on adjacent spinous processes. In this embodiment, a worm drive mechanism is used, similar to that described with reference to FIG. 8C. The worm drive mechanism according to this embodiment includes a threaded shaft 446 extending from the first attachment side 140 and passing through an aperture 448 in a second attachment side 142. According to one embodiment, the threaded shaft 446 can be configured like a threaded bolt integrated with, and extending from, the interior surface of the first attachment side 140. The threaded shaft 446 can be fixed to the first attachment side 140 (either integrated or bolted thereto). A worm gear nut 450 is threadably received by the threaded shaft 446 from the outside of the attachment side 142, holding the second attachment side 142 on the threaded shaft 446. The worm gear nut 450 includes teeth or gearing on its exterior surface which operably meshes with a screw 452 (or other threaded shaft operable for turning by an operator). The screw 452 acts as a worm, causing the worm gear nut 450 to rotate around the threaded shaft 446, which in turn causes the worm gear nut 450 to tighten or loosen on the threaded shaft 446. Accordingly, by rotating the screw 452, such as by using a screwdriver or other instrument received by a head of the screw 452, the worm gear nut 450 can be tightened over the threaded shaft 446, causing the second attachment side 142 to tighten toward the first attachment side 140 over the threaded shaft 446 and a spacer tray (not shown to simplify this illustration).

In one embodiment, the fit of the threaded shaft 446 within the aperture 448 is a relatively tight fit to reduce angular movement of the second attachment side 142 relative to the threaded shaft 446, which may serve to reduce the potential of cross-threading or otherwise interfering with the meshing of the screw 452 with the worm gear nut 450. In other embodiments, however, the fit may be looser, allowing at least partial angular movement of the second attachment side 142 relative to the geared member, such as may be used to allow the attachment sides 140, 142 to be positioned at an angle (i.e., not exactly parallel to each other) to account for differences in the width of adjacent spinous processes. Although FIG. 10 shows a particular orientation and placement of the threaded shaft 446 and the screw 452, any other orientation and/or configuration may be used.

In yet another embodiment of a securing means used to tighten the opposing attachment sides 140, 142 on adjacent spinous processes. In this embodiment, a worm drive mechanism is also used, similar to that described with reference to FIG. 10. However, according to this embodiment, the threaded member extending between the first attachment side 140 and the second attachment side 142 is configured differently. In this embodiment, the threaded member includes a fixed worm gear head positioned on the end of the threaded member extending through the aperture in the second attachment side 142. The fixed worm gear head is in a fixed relationship relative to the threaded member, and which does not thread or otherwise turn independent of the threaded member. The threaded member of this embodiment is further configured to be received by and threaded into a threaded receiver, as is shown in the top view cross-sectional illustration. A screw operably meshes with the fixed worm gear head, and is configured in the same or similar manner as is described with reference to FIG. 10. Accordingly, when turning the screw, the fixed worm gear head causes the threaded member to thread into or out of the threaded receiver of the first attachment side 140, which in turn causes the first attachment side 140 to tighten toward the second attachment side 142.

According to one embodiment, the threaded member has an at least partially tapered end (e.g., configured as a screw), which threads into and out of the threaded receiver. In one embodiment, a threaded member with a tapered end can self tap the threaded receiver; though, in other embodiments, the threaded receiver has complementary threads already formed therein. In other embodiments, the threaded member has a substantially straight shaft with a substantially constant diameter at or near its tip (e.g., configured as a bolt). As described above, the fit of the threaded member within the aperture may be a tight or loose fit.

FIGS. 11A-11D illustrate yet another embodiment of a securing means used to tighten the opposing attachment sides 140, 142 on adjacent spinous processes. This embodiment includes a worm gear configuration, similar to those described with reference to FIG. 10. According to this embodiment, however, the threaded member 451 extending between the first attachment side 140 and the second attachment side 142 is configured differently. In this embodiment, the threaded member 451 also includes a fixed worm gear head 457 (which may also be referred to as a “gear” or “worm gear” fixed on the end of the threaded member 451 extending through an aperture in the second attachment side 142 and operably meshing with the screw 452.

However, the threaded member 451 of this embodiment is further configured to be received by and threaded into a floating receiving member 459 retained on the exterior surface of the first attachment side 140, as is shown in more detail in FIG. 11C. The floating receiving member 459 includes a threaded orifice having threads complementary to the threads on the surface of the threaded member 451. The floating receiving member 459 is retained on the exterior surface of the first attachment side 140 by one or more pivotable retention means 461, such as, but not limited to, retaining tabs, flanges, hooks, or other members adapted to retain the floating receiving member 459 while still allowing pivoting, rocking, translational, and/or angular movement relative to the attachment side 140. As illustrated in FIG. 11C, the pivotable retention means 461 according to this embodiment includes flanges or tabs 461 a extending from the floating receiving member 459 and cooperating flanges or tabs 461 b extending from the first attachment side 140, overlapping the floating receiving member 459, and loosely fitting between the flanges or tabs 461 a, thus retaining the floating receiving member 459 in place. According to this embodiment, the flanges or tabs 461 a, 461 b prevent rotation of the floating receiving member 459 while threading it over the threaded member 451, but still allow at least limited pivoting, rocking, and the like due to the loose fitment of, and play existing between, corresponding flanges or tabs 461 a, 461 b. The floating receiving member 459 thus allows the first attachment side 140 to be angled relative to the threaded member 451 (or an axis existing between the two attachment sides 140, 142) so the attachment sides are not required to be implanted in parallel orientation relative to each other. Moreover, according to one embodiment, the floating receiving member 459 can include one or more slits formed at least partially along the length of the threaded portion, as shown in FIG. 11C, for example, which allows spreading the threaded portion for quick insertion of the threaded member 451 therein and subsequently pressing the threaded portion thereby engaging the threads. In one embodiment having one or more slits, a quick release mechanism may be included that spreads the spacing between the slits and disengages the floating receiving member 459 from the threaded member 451. In yet another embodiment, a floating receiving member 459 can include a threaded portion that is split and further includes a locking screw or other similar feature that will allow fast insertion and quick release of the device.

The securing means includes a screw 452 that operably meshes with the fixed worm gear head 457, such that, when turning the screw 452, the fixed worm gear head 457 causes the threaded member 451 to thread into or out of the floating receiving member 459, which in turn causes the first attachment side 140 to tighten toward the second attachment side 142.

As shown in FIG. 11A, the securing means according to this embodiment optionally includes a casing 453 that at least partially (or entirely, as illustrated) encases the end of the threaded member 451 and the fixed worm gear head 457 extending from the surface of the second attachment side 142 and providing access to the screw 452. The casing 453 can protect the surrounding tissue from irritation or injury that may be caused by the components protruding from the interspinous process spacing device. It is further appreciated that a casing similar to that illustrated in FIG. 11A may be included with any of the other embodiments described herein, such as in a similar manner to at least partially cover components protruding therefrom (e.g., extending from the first and/or the second attachment sides). FIG. 11A also shows at least one set screw 455 threadably extending through the casing 453 for engaging the threaded member 451 upon implantation (not shown for simplicity in FIG. 11B). In other embodiments, a set screw may not be included, but other securing mechanisms may be used to prevent rotation or movement of the threaded member 451 and the second attachment side 142 relative to each other after implant.

FIG. 11D illustrates two interspinous process spacing devices 130, 132 implanted with adjacent spinous processes 120, 122, 124. Although there is no overlap shown between the attachment sides of the two interspinous process spacing devices, it is appreciated that, in various embodiments, the attachment sides may overlap as further described herein.

FIGS. 12A-12B illustrate a different configuration of a nut, which may be used to threadably receive a threaded member, like the threaded member 451 described with reference to FIGS. 11A-11D, according to one embodiment. The hemispherical nut 463 may be formed to have a hemispherical shape (or other shape having an at least partially spherical or domed shape at its apex) for rotatably and pivotally fitting within a concave portion 465 of a first attachment side 140 of an interspinous process spacing device. Although not illustrated in FIGS. 12A-12B, in one embodiment, the first attachment side 140 may further include means for retaining the hemispherical nut with the first attachment side, particularly during implantation, which may include, but is not limited to, one or more clips, flanges, tabs, cages, straps, bands, springs, screws, and the like. For example, according to one embodiment, the first attachment side 140 may further include one or more flanges or tabs similar to the flanges or tabs 461 b described with reference to FIG. 11C, which extend from the first attachment side to at least partially overlap the hemispherical nut 463, without unduly constraining its motion. Similarly, the hemispherical nut 463 may also contain one or more tabs or one or more detents adapted to cooperate with the retaining means extending from the first attachment side 140, which will prevent the hemispherical nut 463 from rotating when threading a threaded member therethrough, but still allow pivoting and rotation of the hemispherical nut 463.

As shown in FIG. 12A, in one embodiment, the hemispherical nut 463 may have one or more slits 467 formed at least partially through its body. The one or more slits 467 permit the hemispherical nut 463 to expand for rapid insertion of a threaded member and subsequent collapsing on the threaded member to engage and secure with complementary threads 469 formed through the hemispherical nut 463. In one embodiment, the one or more slits 467 may be formed so as to extend only partially through the body of the hemispherical nut 463, and may stop before reaching the exterior facing surface of the hemispherical nut 463. Additional inward biasing or tightening members, such as, but not limited to, one or more bands, springs, screws, and the like, may optionally be included to bias or force the slits 467 together and around the threaded member. In another embodiment, as shown in FIG. 12A, the hemispherical nut 463 may be formed from at least two portions 463 a, 463 b (e.g., two equal halves), which are connected at or near the exterior facing end of the hemispherical nut 463. Any means may be used to connect the two (or more) portions 463 a, 463 b of the hemispherical nut 463, such as, but not limited to, one or more screws, bolts, welding, tacking, clamps, bands, pins, flanges, tabs, springs, and the like. In one embodiment, one or more spring members may be contained between the two portions 463 a, 463 b such that the spring member biases the portions in a more separated or open position and will be compressed to a more closed position to engage the threads 469 with a threaded member when the hemispherical nut 463 is pushed into the concave portion 465 of the attachment side. FIG. 4B illustrates the first attachment side 140 from the interior side, showing the fitment of the hemispherical nut 463 within the concave portion 465. In one embodiment, such as is shown by example in FIGS. 4M and 4R, the receiving side of the hemispherical nut 463 at or near the apex is at least partially concave to guide and direct the threaded member into the receiving threads of the hemispherical nut. In another embodiment, a quick release mechanism may further optionally be included, which will act to separate the hemispherical nut 463 to allow for unimpeded or minimally impeded removal of the threaded member from the hemispherical nut 463.

FIGS. 12C-12I illustrate yet another embodiment of a floating receiving member configured as a hemispherical nut formed from two separate halves. In this embodiment, as shown in FIG. 12C, a hemispherical nut 490 includes a first half 490 a and a second half 490 b. According to this embodiment, the hemispherical nut 490 includes a concave portion 492 formed at its apex, which serves to guide and direct the threaded member into the receiving threads 469 of the hemispherical nut 490. FIG. 12D illustrates the exterior facing side of the hemispherical nut 490 and means for retaining the two halves 490 a, 490 b together. According to this embodiment, two opposing sides are recessed, creating recessed portions 493 and first and second ridges 494 a, 494 b through which a combination of screws and springs are inserted to hold the two halves 490 a, 490 b together. Moreover, the recessed portions 493 provide a surface against which retaining tabs or other retaining means are placed to retain the hemispherical nut with the first attachment side, as further described with reference to FIG. 12I.

FIG. 12E illustrates a side view of the hemispherical nut 490 according to this embodiment. As shown by this side view, the second ridge 494 b includes a pair (or any number) of aligned apertures 496 extending through the ridges 494 a, 494 b. In one embodiment, each ridge 494 a, 494 b further includes an additional recessed lip 497 formed with one of the apertures 496 for receiving and retaining a spring that creates an inward biasing force for retaining the two halves 490 a, 490 b together. In this embodiment, only a single recessed lip 497 is formed on each ridge 494 a, 494 b such that one aperture 496 has a recessed lip 497 formed on the first ridge 494 a, and the other aperture 496 has a recessed lip 497 formed on the second ridge 494 b and with the opposite. This allows for springs to be inserted on opposite sides of the ridges 494 a, 494 b and through different apertures, as shown in FIG. 12I. FIG. 12F illustrates a side profile view of the hemispherical nut 490, showing the slit formed between the two halves and the profile of the hemispherical shape and the ridges 494.

FIGS. 12G-12I illustrate a first attachment side 140 and the interoperability of the hemispherical nut 490 therewith, according to one embodiment. FIG. 12G shows the exterior-facing surface of the first attachment side 140, which includes a concave portion 465. The concave portion 465 allows the hemispherical nut 490 to be pivotally and rotatably housed therein, allowing for independent movement of the two attachment sides when implanted to account for different spinous process size and anatomy. FIG. 12H shows the interior facing side of the first attachment side 140 with the hemispherical nut 490 contained within the concave portion of the first attachment side 140. As described above and as is shown in FIG. 12H, the hemispherical nut 490 itself can further include a concave portion 492 that facilitates guiding a threaded member centrally into the threads 469 of the hemispherical nut 490.

FIG. 12I illustrates the exterior-facing surface of the first attachment side 140 having the hemispherical nut 490 retained therein. According to this embodiment, the first attachment side includes one or more retaining members 495 for retaining the hemispherical nut 490 within the concave portion 465 of the first attachment side 140, such as, but not limited to, tabs, arms, flanges, bands, screws, and the like. In this embodiment, the retaining members 495 include two arms attached to the attachment side 140 and extending over the recessed portions 493 of each half of the hemispherical nut 490. The retaining members 495 may be removably attached to the first attachment side 140, such as via one or more screws and the like, or may be permanently affixed or integrated with the first attachment side 140, such as if the hemispherical nut 490 and the first attachment side 140 were manufactured together, or if the hemispherical nut 490 is pressure fitted within the retaining members 495. Moreover, in one embodiment, the retaining members 495 are not secured against the recessed portions 493, but instead provide a loose fit of the hemispherical nut 490 within the attachment side 140 to allow rotating and pivoting.

FIG. 12I also illustrates screws 498 and springs 499 inserted through the apertures 496 of the ridges 494 a, 494 b. As is shown as one example configuration, the first ridge 494 a includes one spring 499 fit within the recessed lip 497 and retained by a screw 498 extending through the set of apertures and both ridges 494 a, 494 b. The second ridge 494 b similarly includes one spring fit within the recessed lip 497 and retained by a screw 498 extending through the other set of apertures and through both ridges 494 a, 494 b. According to this configuration, each screw 498 is inserted in opposite directions through the ridges 494 a, 494 b, retaining a spring 499 on opposite sides of the hemispherical nut 490. However, other screw 498 and spring 499 configurations may be provided, or in some embodiments, a spring may not be included.

It is appreciated that, according to other embodiments, any of the features described with reference to FIGS. 12B-12I may be included in any other embodiment described herein, and any other feature described herein may be included with the embodiments of FIGS. 12B-12I. For example, a quick release mechanism may be included, other floating receiving member configurations may be used, and the like.

FIG. 12J illustrates yet another embodiment of a securing means used to tighten the opposing attachment sides 140, 142 on adjacent spinous processes. This embodiment is configured similar to the embodiment illustrated in and described with reference to FIG. 10; although, instead of an integrated shaft and gear to drive the nut, a removable instrument 460 is used to engage and rotate a geared nut 462 threaded over an end of the threaded shaft 446. Because the instrument 460 is removable and not integrated with the interspinous process spacing device, an additional positioning track 464 is integrated with the second attachment side. The positioning track 464 guides the instrument 460 to align its geared tip 466 with the teeth extending from the surface of the geared nut 462. Although the positioning track 464 is illustrated as being configured in an L shape, any other track configuration may be used. For example, in another embodiment, the positioning track 464 may be configured as a hole aligned to cause the geared tip 466 to mesh with the geared nut. Moreover, in one embodiment, the positioning track 464 may be formed with thick side walls to facilitate maintaining alignment of the instrument 460 within the positioning track and in a vertical (or other desirable) orientation by providing increased surface area to guide the instrument 460. Accordingly, operably meshing the geared tip 466 of the instrument 460 with the geared nut 462 and turning the instrument causes the geared nut 462 to thread on and off of the threaded shaft 446, moving the second attachment side 142 toward the first attachment side.

As described above, the fit of the threaded shaft 446 within the aperture of the second attachment side 142 may be a tight or loose fit. In addition, although FIG. 12J shows a particular orientation of the threaded shaft 446 and the positioning track 464, any other orientation and/or configuration may be used.

FIG. 12K illustrates yet another embodiment of a securing means used to tighten the opposing attachment sides 140, 142 on adjacent spinous processes. According to this embodiment, a geared rack 470 and a ratchet member 472 operate in a manner similar to known cable tie mechanisms. In this embodiment, the geared rack 470 extends from the first attachment side 140 through an aperture 474 formed through the second attachment side 142. The second attachment side 142 includes a ratchet member 472 formed on at least one of its surfaces (shown on the outward-facing surface, but may be on the inward surface in other embodiments). The ratchet member 472 operably engages with the teeth on the geared rack 470 and permits movement in one direction—the direction toward the opposing attachment side 140. The operation of the ratchet member 472, however, restricts movement in the opposite direction (e.g., loosening of the attachment sides 140, 142). In one embodiment, a release mechanism may be included to selectively allow movement in the opposite direction. Accordingly, by tightening the second attachment side 142 toward the first attachment side 140, the ratchet member 472 secures the position of the two sides relative to each other. In one embodiment, a separate insertion instrument (e.g., pliers-type device) is used to achieve enough mechanical advantage to tighten the attachment sides 140, 142 on the spinous processes. An example of such a clamping device is illustrated in and described with reference to FIGS. 13-20 below.

According to one embodiment, the geared rack 470 may be slideably positioned through both an aperture 478 formed in the first attachment side 140 and the aperture 474 of the second attachment side 142, having a head 476 on one end which will abut the outer surface of the first attachment side 140. In one embodiment, the head 476 is domed on the side that will abut the attachment side (i.e., adjacent to the shaft), which permits the geared rack 470 to rotate at least partially within the aperture 478 and allow the two attachment sides 140, 142 to vary in their angular orientation relative to each other and relative to the geared rack 470. In one embodiment, the aperture 478 of the first attachment side 140 is also beveled or bored to accommodate the domed shape of the geared rack 470. Moreover, in one embodiment, the aperture 474 formed in the second attachment side 142 can form a relatively tight fit with the geared rack 470 to provide secure engagement of the ratchet member 472 against the geared rack 470. An aperture 474 creating a tight fit causes the second attachment side 142 to have a substantially constant angular relationship with the geared rack 470 (e.g., perpendicular); however, a looser fit between the head 476 and the aperture 478 in the first attachment side 140 still allows relative angular variation between the two attachment sides (e.g., to accommodate different thicknesses of adjacent spinous processes).

In addition, although FIG. 12K shows a particular orientation of the geared rack 470 and the ratchet member 472, any other orientation and/or configuration may be used.

FIG. 12L illustrates yet another embodiment of a securing means used to tighten the opposing attachment sides 140, 142 on adjacent spinous processes. According to this embodiment, a geared cam 480 is actuated by a shaft and gear 482 operably meshed with the geared cam 480 to cause the lobe of the cam to exert a force against a second attachment side 142, in turn causing it to move toward the first attachment side 140. According to this embodiment, a track 484 (which may be a spacer tray or a separate track) extends from the first attachment side 140 and through an aperture 486 in the second attachment side 142. The geared cam 480 is pivotally fixed to the track 484 via an axle running through the cam 480. Thus, when the shaft and gear 482 is turned, the cam 480 rotates about the axle and the lobe of the cam 480 moves toward or away from the outer surface of the second attachment side 142, causing the second attachment side 142 to move along the track 484 toward or away from the first attachment side 140.

As described above, the fit of the track 484 (and/or spacer tray) within the aperture of the second attachment side 142 may be a tight or loose fit. In addition, although FIG. 12L shows a particular orientation of the geared cam 480, the threaded member track 484, and the shaft and gear 482, any other orientation and/or configuration may be used.

Although not illustrated in every figure, any of those securing means illustrated may further include one or more set screws, securing the second attachment side 142 (or whichever attachment side slides over the spacer tray 150) to the spacer tray 150 or the geared rack, threaded member, threaded bolt, track, etc. when tightened to fix the relative location of the two attachment sides 140, 142. A set screw assembly can extend from the outer surface of the second attachment side 142 and through which a set screw is threaded to exert pressure on, and thus to secure the attachment side 142 to, the spacer tray 150. In other embodiments, more than one set screw assembly can be employed. Moreover, the orientation of the set screw assembly can vary.

In addition, although the embodiments illustrated show the securing means oriented as generally extending from the first attachment side 140 and through the second attachment side 142, it is appreciated that in other embodiments the opposite configuration can be provided, in which the securing means extends from the second attachment side 142 and through an aperture formed through the first attachment side 140.

FIGS. 13-20 illustrate embodiments of a separate insertion instrument (implant inserter) 1110 that is optionally used to exert a clamping pressure on each of the attachment sides 140, 142 when securing the interspinous process spacing device in place against the spinous processes. In one embodiment, the attachment sides 140, 142 may include apertures or indentations shaped and positioned to receive the working ends of the insertion instrument 1110, such that the insertion instrument 1110 may grasp the attachment sides 140, 142, and operable to facilitate aligning and maintaining the insertion instrument 1110 in position. Accordingly, once the two attachment sides 140, 142 are clamped in a closed configuration, the securing means 1120 (e.g., any of those illustrated in and described with reference to FIGS. 1-12 and, optionally or alternatively, a set screw) is operated to secure the second attachment side 142 in place relative to the spacer tray 150 and the first attachment side 140. It is appreciated that any insertion instrument 1110 suitable for applying a clamping force on opposite attachment sides may be used.

For example, FIGS. 13-16 illustrate another embodiment of an insertion instrument 1130 having a different configuration. According to this embodiment, a second arm 1134 is removably attached to a first arm 1132 of the insertion instrument 1130. Thus, during implantation, the first arm, which retains one of the first or the second attachment sides 140, 142, is used to place the one side of the device against the spinous processes via an approximate lateral insertion angle, after which the second arm 1134, which retains the other attachment side, is attached to the first arm and pivots to place the other attachment side against the opposite side of the respective spinous processes, also laterally from the opposite side. Thus, an insertion instrument 1130 according to this embodiment reduces the size of the incision by allowing positioning one attachment side first using a separated first arm 1132. Otherwise, if the two arms 1132, 1134 are attached prior to implant, the insertion instrument 1130 has to open almost twice as wide to permit inserting both attachment sides laterally while the spinous ligament is still intact.

FIGS. 13-16 show an example surgical instrument system for implanting an interspinous process spacing device, having a first arm 1132 having a proximal end, an elongated central portion and distal end. The distal end has an interspinous process spacing device engagement element 1162 for posteriorly engaging a spacer plate or first attachment side 140 of the interspinous process spacing device having a spacer tray 150 extending inwardly therefrom. The surgical instrument system has a second arm 1132 having a proximal end, an elongated central portion and distal end, wherein the distal end has an interspinous process spacing device engagement element 1164 for posteriorly engaging a locking plate or second attachment side 1142 of the interspinous process spacing device having a spacer tray slot 135 therein for receiving the spacer tray 150.

The surgical instrument system has a means for positioning the first arm 1132 and the second arm 1134 in alignment for securing the interspinous process spacing device onto spinal processes. As discussed in more detail below, the means for positioning the first arm 1132 and the second arm 1134 in alignment can be along any portion of the arms 1132, 1134, including at a hinge in the central portion or by a connecting member at the proximal portion, such as a latch or ratchet. As can be seen in this embodiment, the proximal and distal ends of the arms 1132, 1134 are offset to provide an unobstructed view of the distal ends when a surgeon is holding the proximal ends.

In the illustrated embodiment of the surgical instrument system for implanting an interspinous process spacing device, each arm 1132, 1134 has an interspinous process spacing device engagement element 1162, 1164 which has an engagement projection 1170, 1180 which releasably engages an instrument receptacle on the attachment side 140, 142 respectively, of the interspinous process spacing device, a mount 1172, 1182 for movably holding the engagement projection, and an implant guide 1174, 1184 extending distally which engages the outer surface of the attachment sides of the interspinous process spacing device.

As shown in FIGS. 13-16, the engagement projections 1170, 1180 are threaded screws which rotatably ride in the mount 1172, 1182 for engagement with the separate attachment sides 140, 142 of the interspinous process spacing device. The threaded projections are controlled by thumbscrews 192, 194, which can also be remotely operated by a ratchet or other rotatable tool.

In the illustrated embodiment, each arm 1132, 1134 permits at least one of an engaged attachment side 140, 142 of the interspinous process spacing device at least 5 degrees, or at least 10 degrees, and up to 30 degrees, of rotation about an axis defined by the engagement element 1174, 1184 on the distal end of the arm 1132, 1134. This permitted wobble of each or both of the attachment sides allows for implanting the device onto spinous processes with varying shapes and contours prior to securing the desired relative orientation by engaging the securing means 320 (e.g., a set screw) onto the spacer tray 150.

In the illustrated embodiment, the engagement projection 1180 on the second arm 1134 provides access to the securing means on the second attachment side 142 of the interspinous process spacing device to secure the second side 142 to the first side 142. In the embodiment shown, the engagement projection 1180 includes a threaded screw which engages a reciprocal threaded instrument receptacle on the attachment side 142 of the interspinous process spacing device. However, the threaded screw on the second arm 1134 is cannulated to provide access therethrough to the securing means on the second attachment side 142 of the interspinous process spacing device to secure the second side 142 to the first side 140 while the second side 142 is engaged to the second arm 1134. The cannulation permits a surgeon to use a separate securing instrument extending through the engagement element 1164 to secure the implantable device onto a spinous process.

In certain embodiments of the surgical instrument system for implanting an interspinous process spacing device, the size, shape or indicia on each of the insertion instrument receptacle on the first attachment side is different from the size, shape or indicia of the insertion instrument receptacle on the second attachment side. In a coordinated manner, the size, shape or indicia on the device engagement element 1162 corresponds to that of the first attachment side 140, and is different from the size, shape or indicia on the device engagement element 1164 which corresponds to that of the second attachment side 142. As shown the engagement element 1162 has a single laser etch mark to match the second attachment side 142, and the engagement element 1164 has a double laser etch mark to match the first attachment side 140.

In the illustrated embodiment, the proximal ends of the first and second arms 1132, 1134 are releasably connectable at more than one selected distance. In particular, the central portions of the first and second arms 1132, 1134 are releasably and rotatably connectable. In such embodiments, the second arm 1134 is removably and pivotally attachable to the first arm 1132 about an axis for positioning the first arm 1132 and the second arm 1134 in alignment for securing the interspinous process spacing device onto spinal processes.

As shown, the second arm 1134 further comprises a pivot member or pin 1137 located on the central portion, and the first arm 1134 further comprises a pivot channel or slot 1135 with a proximally oriented opening and a distally oriented curved retaining edge 1136, such when the pin 1137 is slideably engaged in the slot 1135 against the retaining edge 1136 the first and second arms 1132, 1134 are removeably and pivotally attached to form a hinge, wherein the hinge permits positioning the first arm 1132 and the second arm 1134 in alignment for securing the interspinous process spacing device onto spinal processes.

In use, when the first and second arms 1132, 1134 each have a respective first and second attachment side 140, 142 of the interspinous process spacing device engaged thereto, and the first and second arms 1132, 1134 are attached at the hinge, drawing the proximal ends of the arms together will align and insert the spacer tray 150 into the spacer tray slot 210 of the first and second attachment sides 140, 142 of the interspinous process spacing device, for securing the interspinous process spacing device onto spinal processes.

As shown in FIGS. 13-16, the first arm 1132 further comprises a releasable locking mechanism for selectively securing the pin 1137 of the second arm 1164 into the slot 1135 of the first arm 1132. In certain embodiments, the releasable locking mechanism is a leaf spring 1139 on the central portion of the first arm 1132 in blocking communication with the slot 1135, such that the pin 1137 on the second arm 1164 can deflect the leaf spring 1139 during insertion into the slot 1135 and remain therein when the leaf spring 1139 returns to blocking communication to maintain the pin 1137 against the retaining edge 1136 on the first arm 1132, and wherein the leaf spring 1139 can be manually disengaged from blocking communication with the slot 1135 to release the pin 1137 and separate the first and second arms 1132, 1134.

As illustrated, the surgical instrument system for implanting an interspinous process spacing device has a means for mechanically actuating the insertion instrument to close and open the first arm 1132 and the second arm 1134 for tightening the second attachment side 142 relative to the first attachment side 140. In certain embodiments, the means for mechanically actuating is a ratchet bar 1190 pivotally mounted to the proximal end of the second arm 1134 and selectively engageable to the proximal end of the first arm 1132, wherein the ratchet bar 1190 has a plurality of teeth 1195 on the proximal surface thereof which engage a corresponding flange 1296 on the proximal end of the first arm 1132. The ratchet bar 1190 has a threaded track and a nut 1192 riding thereon outside the proximal end of the first arm for mechanically forcing the proximal ends of the arms 1132, 1134 together.

According to the embodiment of FIGS. 13-16, the first arm 1132 may include a pivot channel 1135 which is at least partially open to receive and retain a pivoting member 1137 extending from the second arm 1134. Although an angled pivot channel 1135 is illustrated, the pivot channel 1135 may be embodied in any number of other various shapes, configurations, and/or dimensions that allow removably attaching and securing the second arm 1134 to the first arm 1132 and that allow the two to pivot relative to each other. To attach the second arm 1134 to the first arm 1132 after one attachment side has been inserted into the patient, the pivoting member 1137 of the second arm 1134 is inserted into and guided through the pivot channel 1135 and rests at the distal end of the pivot channel 1135 where it is secured but allowed to pivot (e.g., similar to separable shears). Therefore, only the second arm 1134 is pivoted toward the first arm 1132 to insert the other attachment side, while the first arm 1132 remains stationary.

As can be seen in FIGS. 24A-24C, the first arm 1132 may include a pivot channel 1135 which is angled at the opening to receive and retain a pivoting member 1137 extending from the second arm 1134 at a greater variety of angles, analogous to a funnel. The pivoting member 1137 of the second arm 1134 is also angled or chamfered in a manner to facilitate insertion into the pivot channel 1135 at a greater range of angles, in order to ultimately rest at the distal end of the pivot channel 1135 where it is secured but allowed to pivot. Thus, the second arm 1134 can be engaged with the first arm 1132 with a greater degree of variability by the user, due to the respective chamfer and funnel configurations, and then can be secured to pivot toward the first arm 1132 to insert the other attachment side, while the first arm 1132 remains stationary.

With reference to FIGS. 17-20, the present invention further provides an embodiment of a surgical instrument system for implanting an interspinous process spacing device, comprising a first arm 1232 having a proximal end, an elongated central portion and distal end, wherein the distal end has an interspinous process spacing device engagement element 1262 for posteriorly engaging a spacer plate or first attachment side 140 of the interspinous process spacing device having a spacer tray 150 extending inwardly therefrom. Such an embodiment also has a second arm 1234 having a proximal end, an elongated central portion and distal end, wherein the distal end has an interspinous process spacing device engagement element 1264 for posteriorly engaging a locking plate or second attachment side 142 of the interspinous process spacing device having a spacer tray slot 210 therein for receiving the spacer tray 150. This embodiment further includes a compressor tool 1200 for positioning the first arm 1232 and the second arm 1234 in alignment for securing the interspinous process spacing device onto spinal processes.

As illustrated, the compressor tool 1200 has a proximal handle end a central portion and a distal pair of opposing tangs 1222, 1224 moveable throughout a range between an open position and a compression position. In certain embodiments, the distal end of each arm 1232, 1234 comprises compressor tool guide channels 1242, 1244 and compression point indentations 1246, 1248 therein for receiving the compressor tool tangs 1222, 1224. In certain embodiments, the tangs 1222, 1224 have distal compressor tips 1252, 1254 extending inwardly for engagement within the corresponding guide channels 1242, 1244 and compression point indentations 1246, 1248 on the arms 1232, 1234, wherein the compression tool 1200 can rotate about an axis defined by the compressor tips 1252, 1254 so as to provide a user with a range of approach angles for compressing the arms 1232, 1234 to secure the aligned interspinous process spacing device onto spinal processes.

In the illustrated embodiment of the surgical instrument system for implanting an interspinous process spacing device, the proximal end of the second arm 1234 further comprises a retaining latch 1280 disposable on the distal end of the first arm 1232 to retain the arms in position relative to each other and in alignment for securing the interspinous process spacing device onto spinal processes. The latch 1280 can have a series of corresponding indentations for engagement on the first arm 1232. The retaining latch 1280 the proximal end of the second arm 1234 can also have a series of transverse interlinking members, in a ladder configuration, for the proximal end of the first arm 1232 to engage and lock at different spacing intervals. This ladder configuration permits more stability of the first and second arms 1232, 1234 of the instrument when engaged for single-handed use, while the other hand of the user is available for manipulating the compression tool 1200.

In certain embodiments, the surgical instrument system for implanting an interspinous process spacing device has a means for mechanically actuating the insertion instrument to close and open the first arm 1232 and the second arm 1234 for tightening the second attachment side 142 relative to the first attachment side 140. As shown, the means for mechanically actuating is a ratchet bar 1290 pivotally mounted to the proximal end of the second arm 1234 and selectively engageable to the proximal end of the first arm 1232, wherein the ratchet bar 1290 has a plurality of teeth 1295 on the proximal surface thereof which engage a corresponding flange 1296 on the proximal end of the first arm 1232. The ratchet bar 1290 has a threaded track and a nut 1292 riding thereon outside the proximal end of the first arm 1232 for mechanically forcing the proximal ends of the arms 1232, 1234 together.

The insertion instrument can further include a flattened surface at or near the pivot point of the instrument. The flattened surface is adapted for striking with a mallet or tamp during insertion of the device to seat each attachment side. It is appreciated that, while the flattened surface can be integrated with the first arm of the insertion instrument, in other embodiments, a flattened surface may be integrated with another portion of the insertion instrument; however, it may be desirable to orient the flattened surface substantially above the device when implanted.

Moreover, according to alternative embodiments, the insertion instrument can further include one or more channels or partial channels (e.g., C- or U-shaped channels, etc.) formed in at least one of the arms through or alongside of which a tightening instrument (e.g., a screwdriver) can be inserted to operate the securing means. For example, according to one embodiment, the first arm includes a channel running at least partially along the length of the first arm. The orientation of the channel directs the tightening instrument through the channel to align with the securing means. For example, if the securing means includes a screw or other rotating mechanism, the insertion instrument can be configured such that when aligned with and attached to the interspinous process spacing device, the first channel aligns with the head of the screw or other rotating mechanism. In other embodiments, one or more additional channels may be formed in an arm of the insertion instrument, such that the additional channel or channels align with a set screw used to fix the position of the second attachment side relative to the first attachment side. In yet another embodiment, a rotating channel, which may be formed as a sleeve that rotates around the axis of the first arm, and indexed to stop at the desired orientations, is used to align with both the securing means and the set screw. In other embodiments, a single channel may be used to align a tightening instrument by re-positioning the arm of the insertion instrument to achieve the desired alignment.

As shown in FIGS. 13-16, the distal portion of each of the arms 1132, 1134 of the insertion instrument 1130 further includes a retaining means 1162, 1164, respectively, for grasping or otherwise retaining the respective attachment side during implantation. In one embodiment, the retaining means on the first arm 1132 includes a first peg having a non-circular cross-sectional shape, such that it is insertable into a correspondingly shaped orifice formed in the respective attachment side (e.g., the second attachment side 142) and provides a friction fit for retaining the attachment side to the first arm 1132. The non-circular shape prevents the attachment side from rotating on the first arm 1132 during implantation. In this embodiment, the retaining means on the second arm 1134 may include a second peg or pin having a circular cross-sectional shape, which is also insertable into a correspondingly shaped orifice formed in the respective attachment side (e.g., the first attachment side 140). Thus, during implantation, while the second attachment side 142 is in a fixed orientation when retained by the insertion instrument 1130, the first attachment side 140 can rotate, which allows for easier alignment of the spacer tray extending from the first attachment side 140 into the slot of the second attachment side 142 and alignment of the securing means (e.g., threaded member) extending from the second attachment side into the receiving means (e.g., floating nut or hemispherical nut) of the first attachment side. In some embodiments, the floating, rotating, and/or pivoting behavior of the receiving means (e.g., floating nut or hemispherical nut) and the advantageously shaped interior surfaces (e.g., a concave shape, etc.) improve the ability to align the spacer tray and/or securing means while bringing the two sides together. It is appreciated that any other means for retaining attachment sides by the insertion instrument 1130 may be included, such as, but not limited to, one or more clips, brackets, clamps, releasable straps, and the like. For example, in another embodiment, the distal ends of each arm 1132, 1134 may be formed in a C-shaped or bracket-shaped clamp, within which a respective attachment side is retained.

It is appreciated that the insertion instrument configurations described herein are provided for illustrative purposes, and that any other configuration and any other orientation relative to the interspinous process spacing device may be used. For example, according to one embodiment, tightening or clamping means similar to any of the securing means described, or any variation thereof, may be integrated with an insertion instrument and between the two arms. In this embodiment, after positioning an interspinous process spacing device to a patient's spinous processes, the tightening or clamping means may be used to tighten the device and secure it to the spinous processes, while other securing means on the device (e.g., those described, or simpler means, such as a set screw, ratchet, pin, screw, etc.) can be used to retain the device in its secured position. It is appreciated that, in some embodiments, clamping or tightening means integrated with a clamping instrument may differ from those described, and may include one or more screws, one or more ratchets, one or more levers, one or more geared mechanisms, and the like.

In addition, it may be advantageous to provide two different insertion instruments, one configured for an interspinous process spacing device being implanted in one orientation and the other configured for an interspinous process spacing device being implanted in the opposite orientation. According to some embodiments, as described herein, at least one arm of an insertion instrument may include features specifically designed to interface with a particular attachment side (e.g., the first retaining means 1162 configured specifically for retaining the second attachment side 142 and the second retaining means 1164 configured for retaining the first attachment side 140, or the channel 1140 oriented to align with the worm gear screw of the securing means, etc.). Thus, without reconfiguring the orientation of these features and without changing the orientation of the handles, a physician would have to change sides of the patient when implanting devices having opposite orientations, which is very impractical and highly undesirable. For example, the screw driving the worm gear in the first and second interspinous process spacing devices are on one side, while the screw of the third interspinous process spacing device is on the opposite side. Accordingly, to prevent the physician from having to switch patient sides during implantation, a second insertion instrument can be formed as essentially the mirror image of the insertion instrument illustrated and described, such that the handles would be operated from approximately the same angle, but the features of the insertion instrument operably align with the device as designed.

However, in another embodiment, a universal insertion instrument may be provided, such that the retaining means extending from the distal ends of each arm of the instrument is configured to have substantially the same shape and orientation. Thus, the retaining means will integrate with either attachment side of an interspinous process spacing device, regardless of the device's orientation. For example, one way to achieve this universal fitment of the insertion instrument is with two pins extending from the distal ends of each attachment arm, the pins being configured the same on each arm. The first attachment side (e.g., the side that does not include the securing means, such as with a floating nut or other receiving member) can be configured with a complementary orifice for receiving one of the two pins while the other pin does not engage or interfere with the first attachment side. The second attachment side, however, can be configured with two complementary orifices such that the two pins are insertable into the two orifices. When installing the second attachment side, both pins are inserted therein, and when installing the first attachment side, only one pin is inserted while the other pin hangs free of the first attachment side. Thus, the operator need not switch between insertion instruments depending upon the orientation of the interspinous process spacing device being implanted.

The present invention also provides a surgical instrument for selecting an interspinous process spacing device, as exemplified in FIGS. 21A-21D. The selection instrument 800 comprises a first arm 810 having a proximal end, an elongated central portion and distal end, wherein the distal end has a first interspinous process spacing measurement wing 814 extending therefrom comprising a first spinous process stop element 812 and a perpendicularly extending wing template 816, a second arm 820 having a proximal end, an elongated central portion and distal end, wherein the distal end has a second interspinous process spacing measurement wing 824 extending therefrom comprising a second spinous process stop element 822 and a perpendicular wing template 826. The first and second arms 810, 820 are pivotally attached about an axis 830 for positioning the first and second interspinous process spacing measurement wings 814, 824 to measure space between adjacent spinal processes.

The measurement device 800 can further comprise first and second wing templates 816, 826 adapted to overlap respective first and second adjacent spinal processes to determine space available on each spinous process for engaging an interspinous process implant. The instrument shown is adapted such that the proximal end of the second arm 820 has a measuring element 840 attached thereto with indicia to register length to the proximal end of the first arm 810, wherein said length corresponds to space between adjacent spinal processes as measured by the first and second spinous process stop elements 812, 822. Therefore, drawing the proximal ends of the arms 810, 820 together separates the wings 814, 824 to measure space between adjacent spinal processes. In one embodiment, the first or second wing template, or both, comprises a fastener template extending therefrom adapted to engage with a slot on an attachment side of an interspinous process spacing device previously implanted to determine space and orientation available for overlapping engagement of a link plate onto a base plate.

FIGS. 25A-25C illustrate a rasping tool 1300 of the present invention for removing excess tissue from the interspinous space to prepare for insertion of an interspinous process implant. The rasping tool 1300 comprises a first arm 1310 having a proximal end, an elongated central portion and distal end, wherein the distal end has a first interspinous process stop element 1312, extending therefrom, and a second arm 1320 having a proximal end, an elongated central portion and distal end, wherein the distal end has a second spinous process stop element 1322 extending therefrom. The first and second arms 1310, 1320 are pivotally attached about an axis 1330 for spreading apart the first and second interspinous process stop elements 1312, 1322 in order to remove successively larger areas of tissue from between adjacent spinal processes, in preparation for placing a spacer tray of the implant device therethrough. The tips of the interspinous process stop elements 1312, 1322 can be pointed and interface together in a split bullet configuration, as shown. The outside surfaces of the interspinous process stop elements 1312, 1322 can be configured with textured, abrasive, serrated, or sharpened features as shown for the removal of tissue by back-and-forth rasping movement of the tool 1300.

As the proximal ends of the arms 1310, 1320 are brought together by the user, the interspinous process stop elements 1312, 1322 separate to create a larger rasping space. The rasping tool 1300 is also shown with the proximal end of the second arm 1320 adapted with a hinged latch and measuring element 1340 attached thereto with indicia to maintain and register the length to the proximal end of the first arm 1310. The registered length on the hinged element 1340 corresponds to the space between adjacent spinal processes as measured by the outer surfaces of the first and second spinous process stop elements 1312, 1322. The arms 1310, 1320 are maintained in position by the countervailing forces of a separation biasing element 1350 and the notched latch element 1340. Therefore, drawing the proximal ends of the arms 1310, 1320 together separates the distal ends of the interspinous process stop elements 1312, 1322 to allow clearing and measurement of the space between adjacent spinal processes. When the desired interspinous space has been cleared by the rasp, the notched latch and measuring element 1340 can engage the arms 1310, 1320 together, and the numbered indicia on the element 1340 in turn corresponds to the suitable width size available from among the spacer trays provided by the invention, as shown in FIGS. 6A and 6B, for optimization of indwelling implantation.

FIG. 1 illustrates further detail of a top perspective view of embodiments of interspinous process spacing devices implanted in an overlapping fashion. FIG. 1 shows a first interspinous process spacing device 130 having substantially flat attachment sides 140, 142, which is illustrated in FIG. 1 as being the one inferiorly located device, such as any of the interspinous process spacing devices illustrated in and described with reference to FIGS. 2-12. In addition, according to some embodiments of the invention, a second (and subsequent) interspinous process spacing device 132 is implanted on adjacent spinous processes, which includes attachment sides 144, 146 having a bent configuration. According to one embodiment, the bent configuration is created by having a substantially flat end 148, which, when implanted, will lie along approximately the same plane as the entire attachment side of the adjacent inferior interspinous process spacing device (e.g., the attachment sides 140, 142 of the first interspinous process spacing device 130 per FIG. 1), and an offset end 149, which will overlap the adjacent end of the inferior (or superior, though not illustrated in this manner) interspinous process spacing device. The offset of the offset end 149 can be approximately equal to, or slightly larger or smaller than, the thickness of the anticipated adjacent attachment side (e.g., the thickness of an attachment side 140, 142 of the first interspinous process spacing device 130).

Accordingly, at least one end of each attachment sides 140, 142 of the first interspinous process spacing device 130 and the offset end 149 of the second interspinous process spacing device 132 includes an integration means for integrating an offset end 149 of the second interspinous process spacing device 132 with a respective attachment side of the first interspinous process spacing device. The embodiment includes an integration means having one or more apertures 240 formed in the outer surface to receive at least a portion of fasteners 220 extending from the inner surfaces of the offset ends 149 of the respective attachment sides 144, 146. The fasteners 220 of the offset ends extending through the apertures 240 can be interlocking posts or be extended sharpened bone fasteners, such as spikes, for engaging a spinous process through the aperture. The apertures 240 permit the attachment sides 144, 146 of the second interspinous process spacing device 132 to integrate and interlock with the attachment sides 140, 142 of the first interspinous process spacing device 130.

According to one embodiment, the number of apertures 240 in the first interspinous process spacing device 130 equals the number of fasteners 220 extending from the second interspinous process spacing device 132. However, in other embodiments, there may be more apertures 240 than fasteners 220 to allow for selective adjustment of the relative orientation of the two interspinous process spacing devices 130, 132 by selecting from multiple positions created by the various aperture locations 240. Apertures may be provided in an overlapping or inch worm pattern for finer adjustments of spacing and angles between each pair of spacing plates. Moreover, in one embodiment, the apertures 240 and corresponding fasteners 220 may have a turning/locking configuration, such that the fasteners 220 can selectively lock (e.g., by turning, snapping, etc.) within the apertures 240 when in position. In addition, the apertures 240 may be sized and shaped larger than the diameter of the corresponding fasteners 220, to permit adjusting the position and orientation of the second interspinous process spacing device 132 relative to the already secured first interspinous process spacing device 130. In other embodiments, however, the apertures 240 may be any configuration. Moreover, in one embodiment, slots may not be provided, and the offset ends 149 of the attachment sides 144, 146 may not include fasteners, but instead may include a rough surface, or other suitable means to secure the two attachment sides. Although only a first and a second interspinous process spacing devices 130, 132, in other embodiments additional interspinous process spacing devices may be added to the second interspinous process spacing device 132 in a similar manner to connect additional spinous processes. Each subsequent interspinous process spacing device would be configured similar to the second interspinous process spacing device 132, including offset ends 149 to overlap with the flat ends 148 of the adjacent interspinous process spacing device. To permit adding another interspinous process spacing device to the second interspinous process spacing device 132, the outer surfaces of the flat ends 148 of the attachment sides 144, 146 also include apertures 240 to receive fasteners, like those shown on the first interspinous process spacing device 130, or any other integration means. Any number of interspinous process spacing devices can be integrated together, permitting fusing a number of spinous processes and providing increased structural integrity over individually and un-integrated known spinous process spacing devices.

For example, in one embodiment in which three interspinous process spacing devices are attached. In this embodiment, the first interspinous process spacing device has substantially flat attachment sides, and the second and third interspinous process spacing devices have bent attachment sides with offset ends for overlapping adjacent devices. In this embodiment, the first interspinous process spacing device is implanted, after which the second and third interspinous process spacing devices are implanted such that each overlaps with a different end of the first interspinous process spacing device (e.g., one implanted superior to and the other implanted inferior to the first interspinous process spacing device). As shown, the second and third interspinous process spacing devices are oriented 180 degrees relative to each other to allow the offset ends of the bent attachment sides to overlap the attachment sides of the first interspinous process spacing device, depending upon whether being attached superior to or inferior to the first interspinous process spacing device. Thus, rotating the subsequent interspinous process spacing devices, if necessary, avoids having to manufacture two different interspinous process spacing device configurations—one for attaching superior to a flat device and one for attaching inferior to a flat device. Because the location of the securing means may differ when an interspinous process spacing device is rotated, different insertion instruments may be provided to accommodate the differing orientations of the device components.

In another embodiment, in which a stub implant is provided, instead of a first interspinous process spacing device. The stub implant simply consists of two stub sides proportioned to engage a single spinous process, and not intended to span two adjacent spinous processes. Accordingly, instead of attaching a second interspinous process spacing device to a first device, it is attached to a stub implant. In operation, the second interspinous process spacing device and the stub implant are likely implanted together, as the two stub sides are secured by the pressure exerted by the second interspinous process spacing device. Like the other interspinous process spacing devices, the stub sides can also include fasteners extending from their inner surfaces for securing to the spinous process, and apertures formed in their outer surfaces for receiving fasteners of the overlapping interspinous process spacing device, or any other integration means. This embodiment may serve to reduce the manufacturing costs, requiring only a single design for the interspinous process spacing device, and smaller, much simpler design for the stub implant.

FIGS. 7A-7E illustrate other example embodiments of an interspinous process spacing device that is configured for implanting at the L5-S1 vertebrae. As shown, an L5-S1 interspinous process spacing device 530 includes first and second attachment sides 540, 542, each having an angled end 545 and an opposite flat end 547 with various spiked bone fasteners 525 extending inwardly. The angled ends 545 allow better fit with the anatomy of a patient's sacrum. In certain embodiments not shown, the angled ends may be further adjustable with respect to the central portion of the device to match the angle on the patient's sacrum. The L5-S1 interspinous process spacing device 530 may include any securing means, such as are illustrated in and described herein, and any integration means. Moreover, in a base plate embodiment such as that illustrated in FIGS. 7A-7C with apertures 550 in the flat end 547, an additional interspinous process spacing link device can be implanted superior to the L5-S1 interspinous process spacing device 530 in an overlapping configuration by overlapping bent attachment sides of the superior interspinous process spacing device with the flat ends 547 of the L5-S1 interspinous process spacing device 530. However, in a link plate embodiment such as that illustrated in FIGS. 7D-7E, with fasteners 520 on an offset flat end 547, the L5-S1 interspinous process spacing device 530 has bent attachment sides such that the ends opposite the angled ends 545 are offset and overlap flat ends of a superior interspinous process spacing device. In certain embodiments, the bone fasteners 525 extend from opposing plates toward the bone at different opposing points to reduce the risk of bone fracture.

FIG. 7B illustrates a view of a second attachment side 542 of an L5-S1 interspinous process spacing device 530. As shown, the angled end 545 of the second attachment side 542 may optionally include one or more apertures 550 for receiving one or more fastening means therethrough. Because the sacrum is typically more dense than spinous processes, one means to secure an L5-S1 interspinous process spacing device 530 to the sacrum includes fastening directly thereto through the one or more apertures 550, such as via screws, set screws, and the like. In particular, an angled fastener 555 can be provided at an angle different from the angle at which other fasteners 525 extend. In some embodiments such as shown, the angled fastener 555 is a bone screw and the other bone fasteners 525 are bone spikes, although any combination of movable, immovable, or expandable bone fasteners can be used.

FIG. 7A illustrates a side view of the interior surface of a second attachment side 542 of a L5-S1 interspinous process spacing device 530. In this embodiment, one or more fasteners 525, similar to the fasteners 225 described with reference to FIG. 2A, extend from the interior of the angled end 545 of the L5-S1 interspinous process spacing device 530. However, because of the orientation of the angled end 545 relative to the patient's sacrum, the fasteners 525 may extend at an angle other than 90 degrees (either acute or obtuse), such that they correctly engage the sacrum when tightening the two attachment sides together. It is appreciated that the second attachment side 542 is described and illustrated in detail by example, but that the first attachment side 540 may also include one or more apertures and one or more fasteners.

The integration means of certain embodiments includes a textured inner surface formed on the inner surface of the offset end and a textured outer surface formed on the outer surface of an adjacent flat end (on the same interspinous process spacing device or understood that the offset end of one interspinous process spacing device will overlap a portion of the flat end of an adjacent interspinous process spacing device). According to one embodiment, the textured inner surface has radially extending ridges arranged in a starburst or spoked pattern. Similarly, the textured outer surface can have one or more detents or nubs (or other surface patterns) approximately matching the radially extending pattern of the textured inner surface. The textured outer surface has multiple complementary detents to permit selective arrangement of the offset end in more than one position. It is appreciated that, while a radially extending pattern is described, any other textured surface may be applied to the inner and outer textured surfaces.

Moreover, according to one embodiment, the inner surface of the offset end may further include a pin extending inwardly, which can be at least partially inserted into one or more apertures formed in the outer surface of the flat end of the adjacent interspinous process spacing device. The pin can be positioned approximately in the center of the radially extending ridges and three apertures are formed in the flat end approximately in the center of the corresponding radial detents. It is appreciated that any number of pins and any number of apertures may be provided. Moreover, any other orientation of the pins and/or the apertures may be used. For example, according to another embodiment, the apertures may be formed in two dimensions to allow for both anterior/posterior and superior/inferior adjustment.

According to one embodiment shown in FIG. 22A, an interspinous process spacing device is provided as a link wing plate with a first attachment side 2140 (and a corresponding second attachment side, not shown), whereby each attachment side includes an integrating extension fastener 2220, or pin, extending inwardly therefrom. In this embodiment, the fastener 2220 is adjustably carried within an elongated fastener frame 2225 permitting movement from side-to-side to engage a slot in another interspinous process spacing device along a range of distances therefrom. In one embodiment, the fastener 2220 may be secured at a selected position within the fastener frame, such as by a set screw (not shown) on the outer surface thereof, and thereby at a selected distance away from an adjacent interspinous process spacing device. FIG. 22B is a side view of a base plate second attachment side 2142 with a single slot 2240 in each end thereof, such as for engaging an extension fastener 2220 of FIG. 22A.

According to one embodiment shown in FIG. 23A, an alternative interspinous process spacing device is provided as link wing plate with second attachment side 2342 (and a corresponding first attachment side, not shown), whereby each attachment side 2342 has an elongated slot 2340 to receive a fastener from an adjacent plate. FIG. 23B is a side view of an alternative base wing plate with second attachment side 2352 (and a corresponding first attachment side, not shown), whereby each attachment side 2342 has a pair of elongated slots 2340 to receive a fastener from an adjacent plate. In the embodiments shown in FIGS. 23A and 23B, the slots 2340 are elongated to receive a fastener from a second interspinous process spacing device along a range of distances therein. Moreover, the slots 2340 may be narrowed by a clamping mechanism, such as an affixed advancing screw 2350, and thereby tightened to secure a fastener received therein at a desired position.

According to one embodiment shown in FIGS. 26A-H, an interspinous process spacing device 3130 is provided as a base plate with a first attachment side 3140 (and a corresponding second attachment side, not shown) for engaging either side of adjacent spinous processes. The first attachment side 3140 includes a spacer tray 3150 extending in a substantially perpendicular direction from the first attachment side 3140. In use, the spacer tray 3150 may be received within a tray slot of the corresponding second attachment side, as described above with respect to other embodiments. The spacer tray 3150 is configured with surfaces to abut the spinous processes to maintain the spaced apart relationship of the spinous processes. Accordingly, the spacer tray 3150 acts to maintain a minimum distance between adjacent spinous processes to keep the vertebrae apart and relieve pressure on nerve tissue and/or facet joints. The first attachment side 3140 may include fasteners 3225, such as teeth or barbs, for engaging the spinous processes and/or serving as integration means to engage the exterior surface of an adjacent interspinous process spacing device. The first attachment side 3140 also may include an integration means having one or more apertures 3240 formed in an outer surface to receive at least a portion of a fastener extending from an inner surface of a link plate type interspinous process spacing device.

The spacer tray 3150 is shaped to facilitate implantation between adjacent spinous processes and insertion into the tray slot of the corresponding second attachment side. For example, the spacer tray 3150 may have a reduced cross-sectional profile and a tapered width on the leading front edge, which eases insertion between the ligaments occupying the space between adjacent spinous processes. Accordingly, the spacer tray 3150 may be inserted between the ligaments without cutting due to its reduced, tapered, or flattened profile compared to larger, circular cross-sections of conventional devices. Moreover, as shown in FIGS. 26C and 26H, the T-shaped cross section, with the bottom of the T extending medially or downward into the spine provides a supporting lift for the tip of the spacer tray 3150 off of the vertebrae and into the tray slot. Similarly, the tapering cross-section of the tip of the spacer tray into a rounded point facilitates insertion into the tray slot, as well as facilitating insertion through the ligaments. Finally, the arcuate longitudinal cross-section facilitates insertion when both attachment sides are engaged with an insertion tool and being drawn together in an arc.

The spacer tray 3150 also is configured to provide a robust connection between the first attachment side 3140 and the second attachment side to secure the desired relative orientation of the sides for fixation of the spinous processes. For example, the spacer tray 3150 may include a trough 3160 formed in a top surface of the spacer tray 3150, and the trough 3160 may be able to receive part of a securing means extending through the second attachment side. As described above, the securing means may include a set screw extending through a central portion of the second attachment side and contacting the trough 3160 of the spacer tray 3150 received within the tray slot of the second attachment side. The trough 3160 may extend from a proximate end of the spacer tray 3150 adjacent the inner surface of the first attachment side 3140 to a distal end of the spacer tray 3150. Additionally, the trough 3160 may be sloped upwardly from the proximate end toward the distal end, and the trough 3160 may run out toward the distal end. The sloped shape of the trough 3160 may be formed in a linear or arcuate manner. The trough 3160 may include angled sidewalls 3170 extending from the top surface of the spacer tray 3150 to the bottom of the trough 3160. The angled sidewalls 3170 also may extend from the proximate end of the trough 3160 toward the distal end of the trough 3160, and the angled sidewalls 3170 may taper inward as they extend toward the distal end of the trough 3160. The trough 3160 further may include a plurality of grooves 3180 each extending along a width of the bottom of the trough 3160. Accordingly, the grooves 3180 are perpendicular to the length of the trough 3160. In some embodiments, the grooves 3180 may be formed by steps, graduations, serrations, or knurled ridges.

In use, the securing means extends through the second attachment side and is received partially within the trough 3160 of the spacer tray 3150, which secures the first attachment side 3140 to the second attachment side. The angled sidewalls 3170 are configured to guide the securing means toward the bottom of the trough 3160. Additionally, the angled sidewalls 3170 are configured to resist torsional and lateral loading of the connection between the securing means and the trough 3160. Upon tightening of the securing means, the sloped configuration of the trough 3160 resists axial loading of the connection between the securing means and the trough 3160. Therefore, the sloped configuration of the trough 3160 resists separation of the first attachment side 3140 and the second attachment side relative to one another. Finally, the grooves 3180 further increase the frictional resistance of the connection between the securing means and the trough 3160 and thus further resist separation of the first attachment side 3140 and the second attachment side relative to one another. Accordingly, the features of the trough 3160 provide a robust connection for securing the desired relative orientation of the sides for fixation of the spinous processes.

According to another embodiment shown in FIGS. 27A and 27B, an interspinous process spacing device 4130 is provided as a base plate with a first attachment side 4140 (and a corresponding second attachment side, not shown) for engaging either side of adjacent spinous processes. As is shown, the first attachment side 4140 may be configured in a manner similar to the first attachment side 3140 described above and may include corresponding features, although certain differences in structure and function will be described below. The first attachment side 4140 includes a spacer tray 4150 extending in a substantially perpendicular direction from the first attachment side 4140. In use, the spacer tray 4150 may be received within a tray slot of the corresponding second attachment side, as described above with respect to other embodiments. The spacer tray 4150 is configured with surfaces to abut the spinous processes to maintain the spaced apart relationship of the spinous processes. Accordingly, the spacer tray 4150 acts to maintain a minimum distance between adjacent spinous processes to keep the vertebrae apart and relieve pressure on nerve tissue and/or facet joints. The first attachment side 4140 may include fasteners 4225, such as teeth or barbs, for engaging the spinous processes and/or serving as integration means to engage the exterior surface of an adjacent interspinous process spacing device. The first attachment side 4140 also may include an integration means having one or more apertures 4240 formed in an outer surface to receive at least a portion of a fastener extending from an inner surface of a link plate type interspinous process spacing device, as described above with respect to other embodiments.

As noted above, the first attachment side 4140 may be configured for contacting the adjacent spinous processes such that the fasteners 4225 engage and seed into the spinous processes for fixation of the associated vertebrae. In order to enhance such fixation, the wings 4155 of the first attachment side 4140 may have a medial-lateral thickness that varies along the height of the wings 4155 to accommodate the shape of the spinous processes. As is shown, each of the wings 4155 may have a substantially constant thickness along the upper portion 4160 of the wing 4155 and may have a lesser thickness along the lower portion 4170 of the wing 4155. Specifically, along the lower portion 4170, the inner surface of the wing 4155 may taper laterally toward the outer surface of the wing 4155 and away from the spacer tray 4150. In this manner, the lower portions 4170 of the wings 4155 may accommodate the shape of the spinous processes which expand laterally about an interface with the lamina. In certain configurations, an angle α between the inner surface of the upper portion 4160 and the inner surface of the lower portion 4170 may be between 5 degrees and 15 degrees, between 15 degrees and 25 degrees, between 25 degrees and 35 degrees, between 35 degrees and 45 degrees, between 45 degrees and 55 degrees, between 55 degrees and 65 degrees, between 65 degrees and 75 degrees, or between 75 degrees and 85 degrees. It will be understood that the angle α of different configurations may be selected to match the angle of the vertebrae between which the interspinous process spacing device 4130 is implanted.

As is shown, some of the fasteners 4225 of the first attachment side 4140 may be positioned on the upper portions 4160 of the wings 4155, and some of the fasteners 4225 may be positioned on the lower portions 4170 of the wings 4155. Further, the fasteners 4225 positioned on the lower portions 4170 may be offset in the medial-lateral direction from the fasteners 4225 positioned on the upper portions 4160 to accommodate the shape of the spinous processes. Specifically, based on the offset of the fasteners 4225 and the shape of the spinous processes about the interface with the lamina, the wings 4155 may be configured such that the fasteners 4225 on the upper portions 4160 and the lower portions 4170 may engage and seed into the spinous processes at the same time. Accordingly, the wings 4155 of the first attachment side 4140 may be configured to achieve optimal fixation along the height of the spinous processes.

FIGS. 28A-28E illustrate another embodiment of an interspinous process spacing device 4530 that may be configured for implanting at the lamina of the vertebrae or the sacrum. As is shown, the interspinous process spacing device 4530 may be generally configured in a manner similar to the interspinous process spacing device 530 described above and may include corresponding features, although certain differences in structure and function will be described below. The interspinous process spacing device 4530 includes first and second attachment sides 4540, 4542, each having a first angled wing 4545 positioned on one end and a second angled wing 4547 positioned on an opposite end. As is shown, the first angled wing 4545 may be formed as a mirror image of the second angled wing 4547 across a midline of each of the first and second attachment sides 4540, 4542. Alternatively, the first angled wing 4545 may be formed to have a first angle, and the second angled wing 4547 may be formed to have a second angle different from the first angle. The angled configuration of the wings 4545, 4547 may allow the first and second attachment sides 4540, 4542 to accommodate the shape of the patient's lamina or sacrum about the implantation site. In certain configurations, an angle β between the inner surface of the wings 4545, 4557 and the inner surface of the central portion of the attachment side may be between 5 degrees and 15 degrees, between 15 degrees and 25 degrees, between 25 degrees and 35 degrees, between 35 degrees and 45 degrees, between 45 degrees and 55 degrees, between 55 degrees and 65 degrees, between 65 degrees and 75 degrees, or between 75 degrees and 85 degrees. It will be understood that the angle β of different configurations may be selected to match the angle of the vertebrae between which the interspinous process spacing device 4530 is implanted. In certain embodiments not shown, the angled wings 4545, 4547 may be adjustable with respect to the central portion of the device to match the angle of the patient's lamina or sacrum and/or the spinous process of the L5 vertebra.

The interspinous process spacing device 4530 may include any securing means, such as are illustrated in and described herein, and any integration means. For example, various spiked bone fasteners 4525 may extend inwardly from each of the angled wings 4545, 4547. In certain embodiments, the bone fasteners 4525 extend from opposing angled wings 4545, 4547 toward the bone at different opposing points to reduce the risk of bone fracture. As is shown, the bone fasteners 4525 may extend inwardly from the angled wings 4545, 4547 at an angle other 90 degrees (i.e., at an acute or obtuse angle), such that the bone fasteners 4525 seed into the sacrum and the spinous process of the L5 vertebra at an optimum angle to enhance fixation. Although in certain aspects, the embodiment shown in FIGS. 28A-28E has been described as being configured for implanting at the sacrum (i.e., the L5-S1 level), it will be appreciated that the interspinous process spacing device 4530 may be similarly configured to accommodate the shape of the vertebrae at other vertebral levels, including at the L3-4 and L2-3 levels. In this manner, such configurations may include angled wings 4545, 4547 and bone fasteners 4525 that are angled to optimize fixation at such levels.

FIGS. 29A-29C illustrate yet another embodiment of an interspinous process spacing device 4730 that may be configured for implanting at the lamina of the vertebrae or the sacrum. As is shown, the interspinous process spacing device 4730 may be generally configured in a manner similar to the interspinous process spacing device 530 and the interspinous process spacing device 4130 described above and may include corresponding features, although certain differences in structure and function will be described below. The interspinous process spacing device 4730 includes first and second attachment sides 4740, 4542, each having a straight wing 4745 positioned on one end and an angled wing 4747 positioned on an opposite end. As is shown, the straight wings 4745 may be fixed relative to the first and second attachment sides 4740, 4742, respectively. In contrast, the angled wings 4747 may be movable relative to the first and second attachment sides 4740, 4742, respectively. Specifically, as is shown in FIGS. 29B and 29C, the angled wings 4747 may be configured to pivot in the medial-lateral direction about a pivot joint 4749. In this manner, the pivotable configuration of the angled wings 4747 may allow the first and second attachment sides 4740, 4742 to accommodate the shape of the lamina or sacrum. In other embodiments not shown, both the straight wing 4745 and the angled wing 4747 may be configured to pivot in the medial-lateral direction about a pivot joint 4749. In still other embodiments not shown, each of the first and second attachment sides 4740, 4542 may include a first angled wing 4747 positioned on one end and a second angled wing 4747 positioned on an opposite end, wherein both the first angled wing 4747 and the second angled wing 4747 may be configured to pivot in the medial-lateral direction about a pivot joint 4749.

The interspinous process spacing device 4730 may include any securing means and any integration means, such as are illustrated in and described herein. For example, various spiked bone fasteners 4725 may extend inwardly from each of the straight wings 4745 and the angled wings 4747. In certain embodiments, the bone fasteners 4725 extend from opposing straight wings 4745 and angled wings 4747 toward the bone at different opposing points to reduce the risk of bone fracture. As is shown, the bone fasteners 4725 may extend inwardly from the straight wings 4745 and the angled wings 4747 at an angle other 90 degrees (i.e., at an acute or obtuse angle), such that the bone fasteners 4725 seed into the lamina, the sacrum, or the spinous process at an optimum angle to enhance fixation. Although in certain aspects, the embodiment shown in FIGS. 29A-29C has been described as being configured for implanting at the sacrum (i.e., the L5-S1 level), it will be appreciated that the interspinous process spacing device 4730 may be similarly configured to accommodate the shape of the vertebrae at other vertebral levels, including at the L3-4 and L2-3 levels. In this manner, such configurations may include straight wings 4745, angled wings 4747, and bone fasteners 4725 that are angled and movable to optimize fixation at such levels. Moreover, in a base plate embodiment such as that illustrated in FIGS. 29A-29C with apertures 4750 formed in the straight wings 4745, an additional interspinous process spacing link device can be implanted superior and inferior to the interspinous process spacing device 4730 in an overlapping configuration by overlapping bent attachment sides of the superior interspinous process spacing device with the straight wings 4745 of the L5-S1 interspinous process spacing device 4730.

According to still another embodiment shown in FIGS. 30A-30C, an interspinous process spacing device 4830 is provided as a link plate that may be configured for implanting at the lamina of the vertebrae or the sacrum. As is shown, the interspinous process spacing device 4830 may be generally configured in a manner similar to the link plate of the interspinous process spacing device 530 described above and may include corresponding features, although certain differences in structure and function will be described below. The interspinous process spacing device 4830 includes a second attachment side 4842 (and a corresponding first attachment side, not shown) for engaging either side of adjacent spinous processes. Moreover, as a link plate, the second attachment side 4842 is configured for attaching to a second attachment side of a superior interspinous process spacing device, such as the second attachment side 142 of the interspinous process spacing device 130, as is shown. The second attachment side 4842 includes an angled wing 4845 positioned on one end and an offset flat wing 4847 positioned on an opposite end. The angled configuration of the angled wing 4845 may allow the second attachment side 4842 to accommodate the shape of the patient's sacrum. The offset configuration of the offset flat wing may allow the second attachment side 4842 to overlap the flat wing of the second attachment side 142.

Similar to the link plate embodiments described above, the offset flat wing 4847 may include an integration means, such as a fastener 4820, for integrating the offset flat wing 4847 with one of the apertures 240 of the second attachment side 142. Upon integrating the fastener 4820 with one of the apertures 240, the second attachment side 4842 may rotatable about the fastener 4820. Accordingly, the second attachment side 4842 may be configured to rotate in the proximal-distal direction to allow the second attachment side 4842 to accommodate the shape of the sacrum. As is shown, the medial-lateral profile of the offset flat wing 4847 may be shaped to enhance the angle of rotation as compared to the offset flat wing 547 of the second attachment side 542 described above. Specifically, the top surface 4850 of the offset flat wing 4847 may have a greater taper angle such that the second attachment side 4842 may be rotated upward to a greater degree before contacting the center portion of the second attachment side 542. In like manner, the bottom surface 4852 of the offset flat wing 4847 may have a greater taper angle such that the second attachment side 4842 may be rotated downward to a greater degree before contacting the center portion of the second attachment side 542. Additionally, the bottom surface 4852 of the offset flat wing 4847 may define a notch 4854 to allow for an even further degree of downward rotation before contacting the center portion of the second attachment side 542. In this manner, the second attachment side 4842 may provide greater flexibility in accommodating the shape of the lamina or the sacrum to achieve optimal fixation. Although in certain aspects, the embodiment shown in FIGS. 30A-30C has been described as being configured for implanting at the sacrum (i.e., the L5-S1 level), it will be appreciated that the interspinous process spacing device 4730 may be similarly configured to accommodate the shape of the vertebrae at other vertebral levels, including at the L3-4 and L2-3 levels. In this manner, such configurations may include angled wings 4845 and offset flat wings 4847 that are angled and rotatable to optimize fixation at such levels. Additionally, although the above-described embodiment has focused on the link plate second attachment side 4842 positioned inferior to the base plate, the features described also may be incorporated in a link plate first attachment side as well as an attachment side positioned superior to the base plate.

FIGS. 31A-31E illustrate a rasp tool 4900 for preparing an implantation site for an interspinous process spacing device and also for selecting an appropriate size device to be implanted. The rasp tool 4900 includes a first arm 4910 having a proximal end, an elongated central portion and distal end, wherein the distal end has a first interspinous process spacing device measurement wing 4914 extending at a generally perpendicular angle therefrom. The rasp tool 4900 also includes a second arm 4920 having a proximal end, an elongated central portion and distal end, wherein the distal end has a second interspinous process spacing device measurement wing 4924 extending at a generally perpendicular angle therefrom. The first and second arms 4910, 4920 are pivotally attached about an axis defined by a pin 4930. In this manner, the first and second interspinous process spacing device measurement wings 4914, 4924 may be positioned at an implantation site and separated by pivoting the first and second arms 4910, 4920 in order to measure a space between adjacent spinous processes. Based on this measurement, an appropriate size interspinous process spacing device may be selected. The rasp tool 4900 further may include biasing elements 4932, such as leaf springs, configured to bias the first and second arms 4910, 4920 apart from one another such that the rasp tool 4900 is in a closed position.

As is shown, the first interspinous process spacing device measurement wing 4914 is formed as an elongated member including a sharp tip 4916 configured to ease insertion of the wing 4914 into the implantation site. The first interspinous process spacing device measurement wing 4914 also includes a cutout 4918 adjacent the sharp tip 4916 configured for receiving the second interspinous process spacing device measurement wing 4924 when the wings 4914, 4924 are in a closed position. Additionally, the first interspinous process spacing device measurement wing 4914 includes a plurality of grooves 4919 formed along an outer surface of the wing 4914 and configured for debriding and preparing the implantation site. The second interspinous process spacing device measurement wing 4924 is formed as an elongated member including a tapered tip 4926 configured for mating within the cutout 4918 of the first interspinous process spacing device measurement wing 4914. The second interspinous process spacing device measurement wing 4924 also includes a plurality of grooves 4929 formed along an outer surface of the wing 4924 and configured for debriding and preparing the implantation site. In this manner, the wings 4914, 4924 may be used as a rasp for contouring bone and tissue about the implantation site to receive the interspinous process spacer device.

The rasp tool 4900 further may include a measurement element 4940 attached to the proximal end of the first arm 4910 and configured to engage the proximal end of the second arm 4920. As is shown, the measurement element 4940 may be formed as a rack including teeth 4944 defined in a distal side of the measurement element 4940 and configured to engage the second arm 4920. The measurement element 4940 also may include predetermined measurement indicia positioned on the proximal side of the measurement element 4940 and configured to correspond to a lateral spacing of the wings 4914, 4924 at a given position of the first and second arms 4910, 4920. In this manner, as the first and second arms 4910, 4920 are pivoted relative to one another and the wings 4914, 4924 are separated or drawn together, the measurement element 4940 will indicate the lateral spacing or overall width of the wings 4914, 4924. Accordingly, the rasp tool 4900 may be used to measure the width of the implantation site between adjacent spinous processes, and thus may be used to select an appropriate size interspinous process spacer device to be implanted.

According to another embodiment shown in FIGS. 32A-E, an interspinous process spacing device 5130 is provided as a base plate with a first attachment side 5140 (and a corresponding second attachment side, not shown) for engaging either side of adjacent spinous processes. As is shown, the first attachment side 5140 may be configured in a manner similar to the first attachment side 3140 described above and may include corresponding features, although certain differences in structure and function will be described below. The first attachment side 5140 includes a spacer tray 5150 extending in a substantially perpendicular direction from the first attachment side 5140. In use, the spacer tray 5150 may be received within a tray slot of the corresponding second attachment side, as described above with respect to other embodiments. The spacer tray 5150 is configured with surfaces to abut the spinous processes to maintain the spaced apart relationship of the spinous processes. Accordingly, the spacer tray 5150 acts to maintain a minimum distance between adjacent spinous processes to keep the vertebrae apart and relieve pressure on nerve tissue and/or facet joints. The first attachment side 5140 may include fasteners 5225, such as teeth or barbs, for engaging the spinous processes and/or serving as integration means to engage the exterior surface of an adjacent interspinous process spacing device. The first attachment side 5140 also may include an integration means having one or more apertures 5240 formed in an outer surface to receive at least a portion of a fastener extending from an inner surface of a link plate type interspinous process spacing device, as described above with respect to other embodiments.

The first attachment side 5140 further may include fasteners 5235 configured for retaining a bone matrix 5300 (shown via phantom lines) or other bone-growth-promoting material and positioning the bone matrix 5300 during implantation of the interspinous process spacing device 5130 to promote bone growth between the adjacent spinous processes. The fasteners 5235 may be positioned about the inner surface of the first attachment side 5140 and configured for retaining the bone matrix 5300 against the inner surface. In this manner, upon implantation of the interspinous process spacing device 5130, the bone matrix 5300 may be positioned at least partially between the adjacent spinous processes to promote bone growth. As is shown, the fasteners 5235 may be positioned about the inner surface of the central portion 5160 of the first attachment side 5140. According to various configurations, one or more of the fasteners 5235 additionally or alternatively may be positioned about the inner surfaces of the wing portions 5155 of the first attachment side 5140. The fasteners 5235 may be formed as hooks, spikes, teeth, or barbs configured for engaging the bone matrix 5300 and resisting migration of the bone matrix 5300 away from the first attachment side 5140.

As is shown, the fasteners 5235 may include one or more upper fasteners 5240 and one or more lower fasteners 5245 configured for retaining at least a portion of the bone matrix 5300 therebetween. The upper fasteners 5240 may extend inwardly from the inner surface of the first attachment side 5140, and the lower fasteners 5245 may extend upwardly from the top surface of the spacer tray 5150. In this manner, the upper fasteners 5240 and the lower fasteners 5245 may define a space therebetween for retaining at least a portion of the bone matrix 5300. According to this configuration, the spacer tray 5150 also may facilitate retention of the bone matrix 5300 by preventing downward migration of the bone matrix 5300. As is shown in FIGS. 32A-E, the upper fasteners 5240 may be formed as hooks including an angled tip portion pointing toward the spacer tray 5150, and the lower fasteners 5245 may be formed as hooks including an angled tip portion pointing toward the first attachment side 5140. According to another embodiment shown in FIGS. 33A-E, the upper fasteners 5240 may be formed as hooks including an angled tip portion pointing toward the spacer tray 5150, and the lower fasteners 5245 may be formed as angled spikes pointing toward the first attachment side 5140. Other configurations of the fasteners 5235 are possible, such as where only the upper fasteners 5240 are included and opposing retention forces are provided by the top surface of the spacer tray 5150, or where only the lower fasteners 5245 are included and opposing retention forces are provided by the inner surface of the first attachment side 5140. Additionally, according to certain configurations, the first attachment side 5140 may include multiple sets of fasteners 5235 in addition to the upper fasteners 5240 and the lower fasteners 5245 shown. For example, additional sets of fasteners 5235 may extend from the inner surface of the first attachment side 5140 and/or from the top surface of the spacer tray 5150. Such fasteners 5235 may include various combinations of hooks, spikes, teeth, or barbs. Further, although the fasteners 5235 are described herein with respect to the first attachment side 5140, the second attachment side additionally or alternatively may include the fasteners 5235 configured in a similar manner for retaining the bone matrix 5300.

The bone matrix 5300 or other bone-growth-promoting material used with the interspinous process spacing device 5130 may be formed of natural bone or various synthetic materials having osteoconductive and/or osteoinductive properties to promote bone growth. For example, the bone matrix 5300 may be a demineralized bone matrix or a synthetic bone graft substitute, such as a bone putty. The bone matrix 5300 may be substantially malleable and thus may conform to the features of the interspinous process spacing device 5130, such as the fasteners 5235, to facilitate retention of the bone matrix 5300 during implantation of the interspinous process spacing device 5130. Further, the bone matrix 5300 may conform to the geometry of the adjacent spinous processes and may fill voids between the interspinous process spacing device 5130 and the spinous processes. The fasteners 5235 may engage the bone matrix 5300 by penetrating corresponding surfaces of the bone matrix 5300. Specifically, the upper fasteners 5240 may penetrate the outer side surface of the bone matrix 5300, and the lower fasteners 5245 may penetrate the bottom surface of the bone matrix 5300, as is shown. The size of the bone matrix 5300 may be selected depending upon the size of the interspinous process spacing device 5130 as well as the geometry of the vertebrae between which the interspinous process spacing device 5130 is implanted. According to certain configurations, the bone matrix 5300 may have a height substantially equal to the distance from the top surface of the spacer tray 5150 to the top surface of the central portion 5160 of the first attachment side 5140. As is shown, the bone matrix 5300 may have a width substantially equal to the width of the spacer tray 5150, for example, between 5 mm and 20 mm. Further, the bone matrix 5300 may have a depth in the medial-lateral direction between 5 mm and 20 mm.

According to certain configurations, surfaces of the interspinous process spacing device 5130 may be formed in a manner to promote bone growth thereabout. For example, surfaces of the first attachment side 5140 and the second attachment side may roughened, scored, etched, or otherwise textured to promote bone growth between and around the features of the surfaces. Such surface texturing may be present on the inner surfaces of the attachment sides, the spacer tray 5150, the fasteners 5225, and/or the fasteners 5240, according to various configurations.

The interspinous process spacing devices and any associated components may be made of any suitable biocompatible material, including, but not limited to, metals, resorbable ceramics, non-resorbable ceramics, resorbable polymers, non-resorbable polymers, and/or any combination and/or alloys thereof. Some specific examples include stainless steel, titanium and its alloys including nickel-titanium alloys, tantalum, hydroxylapatite, calcium phosphate, bone, zirconia, alumina, carbon, bioglass, polyesters, polylactic acid, polyglycolic acid, polyolefins, polyamides, polyimides, polyacrylates, polyketones, fluropolymers, and/or other suitable biocompatible materials and/or combinations thereof.

In use, an example method of implanting at least two interspinous process spacing devices can be understood with reference to FIGS. 1-23. In one embodiment, after gaining access to the surgical implantation site, and removing all necessary tissue, the second attachment side 142 of a first interspinous process spacing device 130 is attached to a securing means 1162 of the first arm 1132 of an insertion instrument 1130 prior to attaching the second arm 1134 to the insertion instrument 1130. The first arm 1132 is used to position the second attachment side 142 against one side of two adjacent spinous processes. Because of the reduced profile of the securing means, such as the threaded member 451 used in a worm gear securing means, the second attachment side 142 may be more easily inserted from a lateral direction through ligaments existing between the two spinous processes (although, the device may also be inserted by removing all or a substantial portion of the ligaments and inserted directly from the posterior direction). The second attachment side 142 may further be seated by striking a flattened surface of the insertion instrument 1130 with a mallet or tamp. The first attachment side is then attached to the securing means 1164 of the second arm 1134 of the insertion instrument 1130, and the second arm 1134 is pivotally attached to the first arm 1132. The physician then squeezes the handles of the insertion instrument 1130 to pivot the first attachment side 140 in place against the opposite side of the same two spinous processes, inserting the spacer tray 150 through the ligaments and aligning with its tray slot 210 on the second attachment side 142, while also operably aligning the securing means extending from the second attachment side 142 with the corresponding receiving member on the first attachment side 140. In one embodiment, a punch instrument may first be used prior to inserting either or both of the first and second attachment sides, 140, 142 to remove a portion of the ligaments to facilitate insertion and alignment of the attachment sides 140, 142. The punch instrument may operate in a manner similar to the insertion instrument 1130, but include a punch (or may simply dilate) that laterally passes through and removes the ligaments when the handles are squeezed together. The two attachment sides 140, 142 are pushed together enough to engage the securing means (e.g., worm screws meshing with the worm gearing, screws through a threaded collar, or shaft and gear meshing with the gearing/rack, etc.). Then, to tighten the attachment sides 140, 142 relative to each other, the operator can operate the securing means (e.g., turn the screw to operate the worm drive mechanism). Because of the ability of each attachment side 140, 142 to pivot relative to the other, the interspinous process spacing device 130 can be tightened against the spinous processes, irrespective of the possible varied thicknesses of each spinous process. Once in a tightened configuration, a set screw assembly may optionally be set to secure the second attachment end 142 to the spacer tray 150. It is appreciated that other insertion instrument embodiments may be used to position and implant an interspinous process spacing device, such as one in which a securing means (e.g., gearing, worm gear, screw, ratchet, etc.) is integrated as part of the insertion instrument, instead of, or in addition to, being integrated with the interspinous process spacing device. Thus, in this embodiment, the tightening can at least partially be achieved by operating securing means of the insertion instrument instead of on the device to both tighten and loosen the insertion instrument.

To implant a second (or subsequent) interspinous process spacing device 132, the same steps are repeated with the exception of aligning the integration means (e.g., fasteners, apertures, domes, pins, etc.) on the inner surfaces of the offset ends 149 (or a straight member) with the outer surfaces of the respective attachment ends of the adjacent interspinous process spacing device 130.

Modifications and variations of the devices and methods described herein will be obvious to those skilled in the art from the foregoing detailed description. Such modifications and variations are intended to come within the scope of the appended claims and the example inventions described herein. 

What is claimed is:
 1. A rasp tool for preparing an implantation site, the tool comprising: a first arm comprising a proximal end and a distal end; a second arm comprising a proximal end and a distal end, wherein the first arm and the second arm are pivotally connected to one another; a first wing extending from the distal end of the first arm, the first wing comprising: a sharp tip positioned at a distal end of the first wing and configured to ease insertion into the implantation site; and a cutout defined along a first side of the first wing; and a second wing extending from the distal end of the second arm; wherein the first wing and the second wing are configured to move between a closed position and an open position by pivoting the first arm and the second arm; and wherein the second wing is received at least partially within the cutout when the first wing and the second wing are in the closed position.
 2. The tool of claim 1, wherein the cutout extends from a top surface to a bottom surface of the first wing.
 3. The tool of claim 1, wherein the cutout is positioned adjacent the sharp tip.
 4. The tool of claim 1, wherein the cutout extends from a proximal end of the first wing toward the distal end of the first wing.
 5. The tool of claim 1, wherein the sharp tip has a conical shape.
 6. The tool of claim 1, wherein the second wing comprises a tapered tip positioned at a distal end of the second wing and configured for mating with the cutout.
 7. The tool of claim 1, wherein the first wing further comprises one or more grooves defined along an outer surface of the first wing and configured for preparing the implantation site.
 8. The tool of claim 7, wherein the one or more grooves are defined along a second side of the first wing opposite the first side of the first wing.
 9. The tool of claim 7, wherein the one or more grooves extend in a direction from a proximal end of the first wing toward the distal end of the first wing.
 10. The tool of claim 7, wherein the second wing comprises one or more grooves defined along an outer surface of the second wing and configured for preparing the implantation site.
 11. The tool of claim 1, wherein the first wing extends from the distal end of the first arm at a generally perpendicular angle, and wherein the second wing extends from the distal end of the second arm at a generally perpendicular angle.
 12. The tool of claim 1, wherein the first wing has a first length from a proximal end to the distal end of the first wing, wherein the second wing has a second length from a proximal end to a distal end of the second wing, and wherein the first length is greater than the second length.
 13. The tool of claim 12, wherein the cutout has a third length from a proximal end to a distal end of the cutout, and wherein the third length is substantially equal to the second length.
 14. The tool of claim 1, further comprising a measurement element attached to the proximal end of the first arm and configured to engage the proximal end of the second arm, wherein the measurement element comprises predetermined measurement indicia corresponding to a lateral spacing of the first wing and the second wing.
 15. A rasp tool for preparing an implantation site, the tool comprising: a first arm comprising a proximal end and a distal end; a second arm comprising a proximal end and a distal end, wherein the first arm and the second arm are pivotally connected to one another; a first wing extending from the distal end of the first arm, the first wing comprising: a conical tip positioned at a distal end of the first wing and configured to ease insertion into the implantation site; and a cutout defined along a first side of the first wing; and a second wing extending from the distal end of the second arm, the second wing comprising a tapered tip positioned at a distal end of the second wing and configured for mating with the cutout; wherein the first wing and the second wing are configured to move between a closed position and an open position by pivoting the first arm and the second arm; and wherein the second wing is received at least partially within the cutout when the first wing and the second wing are in the closed position.
 16. The tool of claim 15, wherein the first wing has a first length from a proximal end to the distal end of the first wing, wherein the second wing has a second length from a proximal end to the distal end of the second wing, and wherein the first length is greater than the second length.
 17. The tool of claim 15, wherein the first wing and the second wing each further comprise one or more grooves defined along an outer surface thereof and configured for preparing the implantation site.
 18. A rasp tool for preparing an implantation site, the tool comprising: a first arm comprising a proximal end and a distal end; a second arm comprising a proximal end and a distal end, wherein the first arm and the second arm are pivotally connected to one another; a first wing extending from the distal end of the first arm, the first wing comprising a conical tip positioned at a distal end of the first wing and configured to ease insertion into the implantation site; and a second wing extending from the distal end of the second arm, the second wing comprising a tapered tip positioned at a distal end of the second wing; wherein the first wing has a first length from a proximal end to the distal end of the first wing, wherein the second wing has a second length from a proximal end to the distal end of the second wing, and wherein the first length is greater than the second length.
 19. The tool of claim 18, wherein the first wing further comprises a cutout defined along a first side of the first wing, wherein the first wing and the second wing are configured to move between a closed position and an open position by pivoting the first arm and the second arm, and wherein the second wing is received at least partially within the cutout when the first wing and the second wing are in the closed position.
 20. The tool of claim 19, wherein the tapered tip is configured for mating with the cutout when the first wing and the second wing are in the closed position. 